U.S. patent number 8,115,930 [Application Number 12/529,477] was granted by the patent office on 2012-02-14 for methods and apparatus for analyzing samples and collecting sample fractions.
This patent grant is currently assigned to Alltech Associates, Inc.. Invention is credited to James M. Anderson, Jr., Bruce D. Black, Josef P. Bystron, Dirk Helgemo, Dennis K. Mc Creary, Washington J. Mendoza, Sheldon Nelson, Neil R. Picha, Carl H. Poppe, Raaidah B. Saari-Nordhaus.
United States Patent |
8,115,930 |
Anderson, Jr. , et
al. |
February 14, 2012 |
**Please see images for:
( Certificate of Correction ) ** |
Methods and apparatus for analyzing samples and collecting sample
fractions
Abstract
Methods and apparatus for analyzing a sample using at least one
detector are disclosed.
Inventors: |
Anderson, Jr.; James M.
(Arlington Heights, IL), Saari-Nordhaus; Raaidah B.
(Antioch, IL), Mendoza; Washington J. (Lake in the Hills,
IL), Bystron; Josef P. (Chicago, IL), Helgemo; Dirk
(Shakopee, MN), Nelson; Sheldon (Plymouth, MN), Black;
Bruce D. (Napa, CA), Picha; Neil R. (Petaluma, CA),
Mc Creary; Dennis K. (Greencastle, PA), Poppe; Carl H.
(Sabastopol, CA) |
Assignee: |
Alltech Associates, Inc.
(Columbia, MD)
|
Family
ID: |
40756028 |
Appl.
No.: |
12/529,477 |
Filed: |
December 4, 2008 |
PCT
Filed: |
December 04, 2008 |
PCT No.: |
PCT/US2008/013359 |
371(c)(1),(2),(4) Date: |
September 01, 2009 |
PCT
Pub. No.: |
WO2009/075764 |
PCT
Pub. Date: |
June 18, 2009 |
Prior Publication Data
|
|
|
|
Document
Identifier |
Publication Date |
|
US 20100238444 A1 |
Sep 23, 2010 |
|
Current U.S.
Class: |
356/436; 356/440;
356/435 |
Current CPC
Class: |
G01N
30/28 (20130101); G01N 30/78 (20130101); G01N
30/82 (20130101); G01N 2030/322 (20130101); G01N
2030/621 (20130101); G01N 30/74 (20130101) |
Current International
Class: |
G01N
21/00 (20060101) |
Field of
Search: |
;356/337-343,436-442 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
|
|
|
|
|
|
|
1380329 |
|
Jan 2004 |
|
EP |
|
1370571 |
|
Jun 2005 |
|
EP |
|
01707957 |
|
Oct 2006 |
|
EP |
|
1348958 |
|
Sep 2008 |
|
EP |
|
0037157 |
|
Dec 1998 |
|
WO |
|
9925451 |
|
May 1999 |
|
WO |
|
9925452 |
|
May 1999 |
|
WO |
|
0026662 |
|
May 2000 |
|
WO |
|
0045929 |
|
Aug 2000 |
|
WO |
|
03021251 |
|
Mar 2001 |
|
WO |
|
0136071 |
|
May 2001 |
|
WO |
|
02063291 |
|
Aug 2002 |
|
WO |
|
02082071 |
|
Oct 2002 |
|
WO |
|
03008101 |
|
Jan 2003 |
|
WO |
|
2005116628 |
|
Dec 2005 |
|
WO |
|
2006042365 |
|
Apr 2006 |
|
WO |
|
2008118808 |
|
Oct 2008 |
|
WO |
|
Other References
Automated Semipreparative Purification with Mass Spectrometric
Fraction Collection Trigger: Modeling and Experimental Evaluation
of a Setup Employing Passive Splitting by Steiner, F., Mahsunah A.,
Arnold F., Piecha T., Huber C.; J. Sep. Sci 2007, 30, 1496-1508.
cited by other .
Blue Natural Organic Dyestuffs--From Textile Dyeing to Mural
Painting. Separation and Characterization of Coloring Matters
Present in Elderberry, Logwood and Indigo by Pawlak, K., Puchalska,
M., Miszczak, A., Rostoniec, E., and Jarosz, M.,; Journal of Mass
Spectrometry 2006; 41: 613-622. cited by other .
High-Throughput Purification of Combinatorial Libraries I: A
High-Throughput Purification System Using an Acclerated Retention
Window Approach by Yan, B., Collins, N., Wheatley, J., Irving, M.,
Leopold, K., Chan, C., Shornikov, A., Fang, L., Lee, A., Stock, M.,
and Zhao, J.; J. Comb Chem. 2004, 6, 255-261. cited by other .
Optimal Fraction Collecting in Preparative LC/MS by Rosentreter, U.
and Huber, U.; Journal of Combinatorial Chemistry, vol. 6, No. 2,
Mar./Apr. 2004. cited by other .
Purification of Alkaloids from Corydalis Yanhusuo W.T. Wang Using
Preparative 2-D HPLC by Zhang, Jing; Jin, Yu; Liu, Yanfang; Xiao,
Yuansheng; Feng, Jiatao; Xue, Xingya; Zhang. Xiuli; Liang, Xinmiao;
J. Sep. Sci. 2009, 31, 1401-1406. cited by other .
Quantification of fipronil and its metabolite fipronil sulfone in
rat plasma over a wide range of concentrations by LC/UV/MS by
Lacroix, M Z; Puel, S; Toutain, P L; Viguioe, C.; J Chromatogr B
Analyt Technol Biomed Life Sci vol. 878, No. 22, May 24, 2010.
cited by other .
Role of mass spectrometry in the purification of peptides and
proteins by Mazza, C. B.; Cavanaugh, J. Y.; Neue, U. D.; Phillips,
D. J.; J. Chromatogr. B Anal. Technol. Biomed. Life Sci vol. 790,
2003. cited by other .
Sample preparation for hyphenated analytical techniques by
Rosenfeld, J.M.; p. 121-123, 2004. cited by other .
Separation and Identification of Compounds in Adinandra Nitida by
Comprehensive Two-Dimensional Liquid Chromatography Coupled to
Atmospheric Pressure Chemical Ionization Source Ion Trap Tandem
Mass Spectrometry by J. Zhang, D. Tao, J. Duan, Z. Liang, W. Zhang,
L. Zhang, Y. Huo, and Y. Zhang. From Anal Bioanal Chem (2006) 386:
586-593. cited by other .
On-Line Sample Enrichment System Coupled to Electrospray Ionization
Time-of-Flight Mass Spectrometry (ESI-TOF-MS) by M. Okamoto, K.
Yamashita, and K. Nakai from Journal of Pharmaceutical and
Biomedical Analysis 41 (2006) 707-713. cited by other .
Liquid Chromatography with Ultraviolet Absorbance-Mass
Spectrometric Detection and with Nuclear Magnetic Resonance
Spectroscopy: A Powerful Combination for the On-Line Structural
Investigation of Plant Metabolites by J. Wolfender, K Ndjoko, and K
Hostettmann from Journal of Chromatography A, 1000 (2003) 437-455.
cited by other .
A Straightforward Means of Coupling Preparative High-Perfromance
Liquid Chromatography and Mass Spectrometry by H. Cai, J.
Kiplinger, W. Goetzinger, R. Cole, K. Laws, M. Foster, and A
Schrock from Rapid Communications in Mass Spectrometry (2002) 16:
544-554. cited by other .
U.S. Appl. No. 12/959,933, filed Nov. 3, 2010, Anderson, James et
al. cited by other .
U.S. Appl. No. 12/960,042, filed Dec. 3, 2010, Anderson, James et
al. cited by other .
U.S. Appl. No. 12/960,114, filed Dec. 3, 2010, Anderson, James et
al. cited by other .
U.S. Appl. No. 13/132,619, filed Jun. 3, 2011, Olsen, Kristine et
al. cited by other .
U.S. Appl. No. 13/133,733, filed Jun. 9, 2011, Anderson, James et
al. cited by other .
U.S. Appl. No. 13/133,837, filed Jun. 9, 2011, Saari-Nordhaus,
Raaidah et al. cited by other .
U.S. Appl. No. 13/139,016, filed Jun. 10, 2011, Bystron, Josef et
al. cited by other .
U.S. Appl. No. 13/139,030, filed Jun. 10, 2011, Bystron Josef, et
al. cited by other .
U.S. Appl. No. 13/139,061, filed Jun. 10, 2011, Saari-Nordhaus,
Raaidah. cited by other .
U.S. Appl. No. 13/262,756, filed Oct. 3, 2011, McCreary Dennis et
al. cited by other .
U.S. Appl. No. 13/266,870, filed Oct. 28, 2011, Saari-Nordhaus
Raaidah et al. cited by other .
On-Line Mass Characterization of Fractions in a Multi-Channel
Preparitive HPLC Environment by Liu, J., Bickler, J., Rahn, P.C., R
& D Biotage, Inc.; Abstracts of Papers American Chemical
Society, vol. 223 (2002). cited by other .
A novel hyphenated LC-ARC-RD-MS-FC system for identification of
drug metabolites; Proceedings of the 50th ASMS Conference on Mass
Spectrometry and Allied Topics, Orlando Florida, Jun. 2-6, 2002 by
Wenzhe Lu, Chung Ping Yu, Dian Y. Lee. cited by other .
Analysis of Rhubarb by Liquid Chromatography-Electrospray-Mass
Spectrometry; Tamkang Journal of Science and Engineering, Vik. 6,
No. 1, pp. 31-36 (2003) by Ming-Ren S. Fuh and Hung-Jian Lin. cited
by other .
Automated simultaneous isolation and quantitation of labeled amino
acid fractions from plasma and tissue by ion-exchange
chromatography; Journal of Chromatography B, 660 (1994) 251-257 by
Hans M.H. van Eijik, Mark P.L. Huinck, Dennis R. Rooyakkers,
Nicolaas E.P. Deutz. cited by other .
Characterization of apolipoprotein and apolipoprotein precursors in
pancreatic cancer serum samples via two-dimensional liquid
chromatography and mass spectrometry; Journal of Chromatography A.
1162 (2007) 117-125 by Jianzhong Chen, Michelle Anderson, David E.
Misek, Diane M. Simeone, and David M Lubman. cited by other .
Evaluation of applicability of the flow splitter to frit-FAB LC-MS
system; Mass Spectroscopy vol. 39, No. 4, Aug. 1991 by Yoshitomo
Ikai, Hisao Oka, Junko Hayakawa, Ken-ichi Harada, and Makato
Suzuki. cited by other .
High-Throughput Mass-Directed Parallel Purification Incorporating a
Multiplexed Single Quadrupole Mass Spectrometer; Anal. Chem. 2002,
74, 3055-3062 by Rongda Xu, Tao Wang, John Isbell, Zhe Cai,
Christopher Sykes, Andrew Brailsford, and Daniel B. Kassel. cited
by other .
Hyphenation of centrifugal partition chromatography with
electrospray ionization mass spectrometry using an active
flow-splitter device for characterization of flavonol glycosides;
Rapid Communications in Mass Spectrometry 2009; 23; 1863-1870 by
Alix Toribio, Emile Desandau, Claire Elfakir, and Michel Lafosse.
cited by other .
Hyphenation of high performance liquid chromatography with sector
field inductively coupled plasma mass spectrometry for the
determination of ultra-trace level anionic and cationic arsenic
compounds in freshwater fish; J. Anal. At. Spectrom., 2004, 19,
191-195 by Jian Zheng and Holger Hintelmann. cited by other .
Identification of intact glucosinolates using direct coupling of
high-performance liquid chromatography with continuous-flow frit
fast atom bombardment tandem mass spectrometry; Biological Mass
Spectrometry, vol. 20, 259-263 (1991) by P.S. Kokkonen, J. van der
Greef, W.M.A. Niessen, U.R. Tjaden, G.J. ten Hove, and G. van de
Werken. cited by other .
Improved liquid chromatography-mass spectrometry performance in
quantitative analysis using a nanosplitter interface; Journal of
Chromatography A. 1053 (2004) 151-159 by Christine L. Andrews,
Chung-Ping Yu, Eric Yang, and Paul Vouros. cited by other .
Novel system for separation of phospholipids by high-performance
liquid chromatography; Journal of Chromatography, 234 (1982)
218-221 by Iftekhar Alam, J. Bryan Smith, Melvin J. Silver, and
David Ahem. cited by other .
Optimization of a liquid chromatography method based on
simulataneous electrospray ionization mass spectrometric and
ultraviolet photodiode array detection for analysis of flavonoid
glycosides; Rapid Communications in Mass Spectometry 2002; 16:
2341-2348 by Filip Cuyckens and Magda Claeys. cited by other .
Quantitation of Radiolabeled Compounds Eluting from the HPLC
System; Journal of Chromatographic Science, vol. 20, Nov. 1982 by
Michael J. Kessler. cited by other .
Rapid analysis of antibiotic-containing mixtures from fermentation
broths by using liquid chromatography-electrospray ionization-mass
spectrometry and matrix-assisted laser desorption
ionization-time-of-flight-mass spectrometry; American Society for
Mass Spectrometry, 1996, 7, 1227-1237 by Bradley L. Ackermann,
Brian T. Regg, Luigi Colombo, Sergio Stella, and John E. Coutant.
cited by other.
|
Primary Examiner: Chowdhury; Tarifur
Assistant Examiner: Pajoohi; Tara S
Attorney, Agent or Firm: Bunch; William D.
Claims
What is claimed is:
1. A method of detecting and collecting one or more sample
components within a sample stream in a chromatography system during
a chromatographic run comprising: generating a composite signal
during the chromatographic run from at least one destructive
detector, including at least one evaporative particle detector; and
at least one non-destructive detector, wherein said composite
signal is a single signal generated from detector response values
from each detector and wherein said detector response values are
generated during said run; and collecting the one or more
components from the stream in a fraction collector during the
chromatographic run in response to a change in the composite signal
during said chromatographic run.
2. The method of claim 1, wherein the composite signal comprises:
(i) detector response values for each detector at a given time,
(ii) the first derivatives of the detector responses at a given
time, (iii the second derivatives of the detector responses at a
given time, or (iv) any combination of (i) to (iii).
3. The method of claim 1, wherein the detector response values are
generated in response to (i) a threshold detector response value
for each detector at a given time, (ii) a first derivative of the
detector response at a given time, (iii) a second derivative of the
detector response at a given time, or (iv) any combination of (i),
(ii), and (iii) from each detector.
4. The method of claim 1, including at least one destructive
detector selected from the group consisting of evaporative light
scattering detectors (ELSD), mass spectrometers (MS), condensation
nucleation light scattering detectors (CNLSD), and corona discharge
detectors.
5. The method of claim 1, including at least one non-destructive
detector selected from the group consisting of optical absorbance
detectors, refractive index detectors (RID), fluorescence detectors
(FD), chiral detectors (CD), and conductivity detectors.
6. The method of claim 1, wherein the non-destructive detector
comprises at least one optical absorbance detector.
7. The method of claim 6, wherein the optical absorbance detector
observes two or more optical wavelengths so as to produce two or
more detector response values.
8. The method of claim 1, wherein the evaporative particle detector
comprises an evaporative light scattering detector.
9. The method of claim 1, wherein the evaporative particle detector
comprises an evaporative light scattering detector and the
non-destructive detector comprises at least one optical absorbance
detector.
10. The method of claim 1, further comprising: actively controlling
fluid flow to the at least one destructive detector via a splitter
pump; a shuttle valve; or a combination of a splitter pump and a
shuttle valve; wherein the splitter pump, the shuttle valve, or the
combination are in fluid communication with the at least one
destructive detector.
11. The method of claim 10, wherein the splitter pump, the shuttle
valve, or the combination removes an aliquot from the sample stream
at a frequency of at least 1 aliquot every 10 seconds.
12. A non-transitory computer readable medium having stored thereon
computer executable instructions for performing the method of claim
1.
13. An apparatus for detecting a sample using the method of claim
1.
14. A chromatographic apparatus for detecting and collecting one or
more components within a sample stream during a chromatographic run
comprising: system hardware operatively adapted to generate a
composite signal that is a single signal from response values
generated by at least one destructive detector, including at least
one evaporative particle detector, and at least one non-destructive
detector during said chromatographic run; and a fraction collector
operatively adapted to collect a fraction in response to a change
in the composite signal during said chromatographic run.
15. The apparatus of claim 14, wherein the composite signal
comprises: (i) detector response values for each detector at a
given time, (ii) the first derivatives of the detector responses at
a given time, (iii) the second derivatives of the detector
responses at a given time, or (iv) any combination of (i) to
(iii).
16. The apparatus of claim 14, wherein the detector response values
are generated in response to (i) a threshold detector response
value for each detector at a given time, (ii) a first derivative of
the detector response at a given time, (iii) a second derivative of
the detector response at a given time, or (iv) any combination of
(i), (ii), and (iii) from each detector.
17. The apparatus of claim 14, including at least one destructive
detector selected from the group consisting of evaporative light
scattering detectors (ELSD), mass spectrometers (MS), condensation
nucleation light scattering detectors (CNLSD), and corona discharge
detectors.
18. The apparatus of claim 14, including at least one
non-destructive detector selected from the group consisting of
optical absorbance detectors, refractive index detectors (RID),
fluorescence detectors (FD), chiral detectors (CD), and
conductivity detectors.
19. The apparatus of claim 14, wherein the non-destructive detector
includes at least one optical absorbance detector.
20. The apparatus of claim 19, wherein the optical absorbance
detector is adapted to observe two or more optical wavelengths so
as to produce two or more detector response values.
21. The apparatus of claim 14, wherein the evaporative particle
detector comprises an evaporative light scattering detector.
22. The apparatus of claim 14, further comprising: a splitter pump;
a shuttle valve; or a combination of a splitter pump and a shuttle
valve; wherein the splitter pump, the shuttle valve, or the
combination are in fluid communication with the at least one
destructive detector.
Description
FIELD OF THE INVENTION
The present invention is directed to methods and apparatus for
analyzing samples and collecting sample fractions with a
chromatography system.
BACKGROUND OF THE INVENTION
There is a need in the art for methods of efficiently and
effectively analyzing samples and collecting sample fractions with
a chromatography system. There is also a need in the art for an
apparatus capable of effectively analyzing samples and collecting
sample fractions.
SUMMARY OF THE INVENTION
The present invention relates to the discovery of methods for
analyzing samples and collecting sample fractions with a
chromatography system. The disclosed methods provide a number of
advantages over known methods of analyzing samples. For example,
the disclosed methods of the present invention may utilize a
splitter pump or a shuttle valve to actively control fluid flow
through at least one detector so that process variables (e.g., flow
restrictions, total flow rate, temperature, and/or solvent
composition) do not negatively impact the fluid flow through the at
least one detector. The disclosed methods of the present invention
may also utilize two or more detectors to provide a more complete
analysis of a given sample, as well as collection of one or more
sample fractions in response to one or more detector signals from
the two or more detectors.
The present invention is directed to methods of analyzing samples
and collecting sample fractions. In one exemplary embodiment, the
method of analyzing a sample comprises the steps of generating a
composite signal from two or more detectors in a liquid
chromatography system, the composite signal comprising a detection
response component from each detector; and collecting a new sample
fraction in a fraction collector in response to a change in the
composite signal. In one embodiment, the composite signal may
comprise (i) a detection response component from at least one
optical absorbance detector (e.g., an UV detector) and (ii) a
detection response component from at least one evaporative particle
detector. In one embodiment, chromophoric or non-chromophoric
solvents may be utilized in the chromatography system as the
carrier fluid. In another embodiment, the composite signal may
comprise (i) a detection response component comprising two or more
detector responses from an optical absorbance detector (e.g., an UV
detector) at two or more specific optical wavelengths and (ii) a
detection response component from an evaporative particle
detector.
In a further exemplary embodiment according to the present
invention, the method of analyzing a sample using chromatography
comprises the steps of using at least one detector to observe the
sample that comprises at least one non-chromaphoric analyte
compound; and collecting a new sample fraction in a fraction
collector in response to a change in a detector response of the
non-chromaphoric compound. The sample may include numerous
different chromaphoric and non-chromaphoric compounds. In addition,
the mobile phase that carries the sample may include one or more
chromaphoric or non-chromaphoric compounds.
In another embodiment, universal carrier fluid may be utilized in
the chromatography system, including volatile liquids and various
gases. In a further embodiment, a non-destructive detector (e.g.,
RI, UV detector, etc.) may be combined with a destructive detector
(e.g., evaporative particle detector, mass spectrometer,
spectrophotometer, emission spectroscopy, NMR, etc.), which enables
detection of various compound specific properties of the sample,
such as, for example, the chemical entity associated with the
peak.
In a further exemplary embodiment, the method of analyzing a sample
comprises the steps of using at least one detector to observe the
sample at two or more specific optical wavelengths; and collecting
a new sample fraction in a fraction collector in response to (i) a
change in a detector response at a first wavelength, (ii) a change
in a detector response at a second wavelength, or (iii) a change in
a composite response represented by the detector responses at the
first and second wavelengths. A change in a given detector response
may include, but is not limited to, a change in a detector response
value, reaching or exceeding a threshold detector response value, a
slope of the detector response value over time, a threshold slope
of the detector response value over time, a change in a slope of
the detector response value over time, a threshold change in a
slope of the detector response value over time, or any combination
thereof. In this embodiment, the method may comprise using n
sensors in at least one detector to observe n specific wavelengths
across a range of an absorbance spectrum, wherein n is an integer
greater than 1; and collecting a new sample fraction in the
fraction collector in response to (i) a change in any one of n
detector responses from the n sensors, or (ii) a change in a
composite response represented by the n detector responses.
In yet a further exemplary embodiment, the method of analyzing a
sample comprises the steps of providing a liquid chromatography
system comprising (i) a chromatography column, (ii) a tee having a
first inlet, a first outlet and a second outlet, (iii) a fraction
collector in fluid communication with the first outlet of the tee,
and (iv) a detector in fluid communication with the second outlet
of the tee; and actively controlling fluid flow through the
detector via (v) a splitter pump positioned in fluid communication
with the second outlet of the tee and the detector. In other
exemplary embodiments, a shuttle valve may be used in place of the
tee and splitter pump to actively control fluid flow through to at
least one detector. In an exemplary embodiment, the shuttle valve
is a continuous flow shuttle valve with the ability to remove very
small sample volumes from the sample stream.
In an even further exemplary embodiment of the present invention, a
method of analyzing a sample of fluid using chromatography includes
the steps of providing a first fluid of effluent from a
chromatography column; providing a second fluid to carry the sample
of fluid to at least one detector; using a shuttle valve to remove
an aliquot sample of fluid from the first fluid and transfer the
aliquot to the second fluid while maintaining a continuous path of
the second fluid through the shuttle valve; using at least one
detector to observe the aliquot sample of fluid; and collecting a
new sample fraction of the first fluid in a fraction collector in
response to a change in a detector response. In one embodiment, a
continuous flow path of the first fluid through the shuttle valve
is maintained when the aliquot sample of fluid is removed from the
first fluid. In another embodiment, continuous flow paths of both
the first fluid and the second fluid through the shuttle valve are
maintained when the aliquot sample of fluid is removed from the
first fluid and transferred to the second fluid.
In another exemplary embodiment according to the present invention,
a method of analyzing a sample of fluid using chromatography
includes the steps of providing a first fluid comprising the
sample; using a shuttle valve to remove an aliquot sample of fluid
from the first fluid without substantially affecting flow
properties of the first fluid through the shuttle valve; using at
least one detector to observe the aliquot sample of fluid; and
collecting a new sample fraction of the first stream in a fraction
collector in response to a change in at least one detector
response. The flow of the first fluid through the shuttle valve may
be substantially laminar, due to the first fluid path or channel
being substantially linear or straight through at least a portion
of the valve. In a further exemplary embodiment, the pressure of
the first fluid through the shuttle valve remains substantially
constant and/or it does not substantially increase. In another
embodiment, the flow rate of the first fluid may be substantially
constant through the shuttle valve. In an alternative embodiment, a
second fluid is utilized to carry the aliquot sample of fluid from
the shuttle valve to the detector(s). The flow of the second fluid
through the shuttle valve may be substantially laminar due to the
second fluid path or channel being substantially linear or straight
through at least a portion of the valve. In an exemplary
embodiment, the pressure of the second fluid through the shuttle
valve is substantially constant and/or it does not substantially
increase. In another embodiment, the flow rate of the second fluid
may be substantially constant through the shuttle valve.
In a further exemplary embodiment, the method of analyzing a sample
comprises the steps of providing a non-destructive system liquid
chromatography system comprising (i) a chromatography column, (ii)
two or more non-destructive detectors (e.g., an optical absorbance
detector such as a UV detector) with no destructive detectors
(e.g., a mass spectrometer) present in the system, and (iii) a
fraction collector in fluid communication with the two or more
non-destructive detectors; and collecting one or more sample
fractions in response to detector signals from the two or more
non-destructive detectors.
In another exemplary embodiment according to the present invention,
a method of analyzing a sample using flash chromatography includes
the steps of using an evaporative particle detector to observe the
sample that is capable of detecting individual compounds; and
collecting a new sample fraction in a fraction collector in
response to a change in a detector response of the compound,
wherein the evaporative particle detector is the only detector
utilized to analyze the sample. The evaporative particle detector
is capable of detecting chemical composition, chemical structure,
molecular weight, or other chemical or physical properties. The
detector may include an ELSD, CNLSD or mass spectrometer.
In yet a further exemplary embodiment, the method of analyzing a
sample comprises the steps of generating a detector signal from at
least one detector in a liquid chromatography system, the detector
signal being generated in response to (i) the slope of a detector
response as a function of time (i.e., the first derivative of a
detector response), (ii) a change in the slope of the detector
response as a function of time (i.e., the second derivative of the
detector response), (iii) optionally, reaching or exceeding a
threshold detector response value, or (iv) any combination of (i)
to (iii) desirably comprising at least (i) or at least (ii); and
collecting one or more sample fractions in response to at least one
detector signal from the at least one detector.
In yet another exemplary embodiment, the method of analyzing a
sample comprises the step of collecting a sample fraction in a
fraction collector of a liquid chromatography system, wherein the
fraction collector is operatively adapted to (i) recognize, receive
and process one or more signals from at least one detector, and
(ii) collect one or more sample fractions based on the one or more
signals.
The present invention is also directed to an apparatus capable of
analyzing a sample. In one exemplary embodiment, the apparatus for
analyzing a sample comprises system hardware operatively adapted to
generate a composite signal from two or more detectors in a liquid
chromatography system, the composite signal comprising a detection
response component from each detector; and a fraction collector
operatively adapted to collect a new sample fraction in response to
a change in the composite signal.
In another exemplary embodiment, the apparatus for analyzing a
sample comprises at least one detector operatively adapted to
observe two or more specific optical wavelengths (e.g., UV
wavelengths); and a fraction collector operatively adapted to
collect a new sample in response to (i) a change in a detector
response at a first wavelength, (ii) a change in a detector
response at a second wavelength, or (iii) a change in a composite
response represented by the detector responses at the first and
second wavelengths. As discussed above, a change in a given
detector response may include, but is not limited to, a change in a
detector response value, reaching or exceeding a threshold detector
response value, a slope of the detector response value over time, a
threshold slope of the detector response value over time, a change
in a slope of the detector response value over time, a threshold
change in a slope of the detector response value over time, or any
combination thereof.
The at least one detector may together comprise n sensors to
observe n specific wavelengths across a range of an absorbance
spectrum, wherein n is an integer greater than 1, and the fraction
collector is operatively adapted to collect a new sample in
response to (i) a change in any one of n detector responses from
the n sensors, or (ii) a change in a composite response represented
by the n detector responses. In one embodiment, the apparatus
comprises a single UV detector comprising n sensors alone or in
combination with one or more additional detectors.
In yet a further exemplary embodiment, the apparatus for analyzing
a sample comprises system hardware that enables generation of a
detector signal from at least one detector in a liquid
chromatography system, the detector signal being generated in
response to (i) the slope of a detector response as a function of
time (i.e., the first derivative of a detector response), (ii) a
change in the slope of the detector response as a function of time
(i.e., the second derivative of the detector response), (iii)
optionally, reaching or exceeding a threshold detector response
value, or (iv) any combination of (i) to (iii) desirably comprising
at least (i) or at least (ii). The apparatus may further comprise a
fraction collector operatively adapted to collect one or more
sample fractions in response to the detector signal from the at
least one detector.
In another exemplary embodiment according to the present invention,
an apparatus for analyzing a sample using chromatography includes
at least one detector that are capable of detecting chromaphoric
and non-chromaphoric analyte compounds in the sample; and a
fraction collector that is capable of responding to a change in a
detector response of the non-chromaphoric compound. The sample may
include numerous different chromaphoric and non-chromaphoric
compounds. In addition, the mobile phase that carries the sample
may include one or more chromaphoric or non-chromaphoric
compounds.
In yet a further exemplary embodiment, the apparatus for analyzing
a sample comprises (i) a chromatography column; (ii) a tee having a
first inlet, a first outlet and a second outlet; (iii) a fraction
collector in fluid communication with the first outlet of the tee;
(iv) a first detector in fluid communication with the second outlet
of the tee; and (v) a splitter pump positioned in fluid
communication with the second outlet of the tee and the first
detector, the splitter pump being operatively adapted to actively
control fluid flow through the first detector. In other exemplary
embodiments, a shuttle valve may be used in place of the tee and
splitter pump to actively control fluid flow through to at least
one detector. In an exemplary embodiment, the shuttle valve is a
continuous flow shuttle valve.
In an even further embodiment according to the present invention,
an apparatus for analyzing a sample of fluid using chromatography
includes a first fluid path of effluent from a chromatography
column or cartridge; at least one detector that is capable of
analyzing the sample of fluid; and a shuttle valve that transfers
an aliquot sample of fluid from the first fluid path to the
detector(s) without substantially affecting the flow properties of
fluid through the first fluid path. The flow of the fluid through
the first fluid path may be substantially laminar, due to the first
fluid path or channel being substantially linear or straight
through at least a portion of the valve. In a further exemplary
embodiment, the pressure of the fluid through the first fluid path
remains substantially constant and/or it does not substantially
increase. In another embodiment, the flow rate of the fluid may be
substantially constant through the first fluid path. In an
alternative embodiment, a second fluid path is utilized to carry
the aliquot sample of fluid from the shuttle valve to the
detector(s). The flow of fluid through the second fluid path may be
substantially laminar due to the second fluid path or channel being
substantially linear or straight through at least a portion of the
valve. In an exemplary embodiment, the pressure of fluid through
the second fluid path is substantially constant and/or it does not
substantially increase. In further embodiment, the flow rate of
fluid may be substantially constant through the second fluid
path.
In an even further exemplary embodiment, an apparatus for analyzing
a sample of fluid using chromatography includes a first fluid path
of effluent from a chromatography column; a second fluid path that
carries the sample of fluid to at least one detector that is
capable of analyzing the sample; and a shuttle valve that transfers
an aliquot sample of fluid from the first fluid path to the second
fluid path while maintaining a continuous second fluid path through
the shuttle valve. In one embodiment, a continuous first flow path
through the shuttle valve is maintained when the aliquot sample of
fluid is removed from the first fluid path. In another embodiment,
continuous first and second flow paths through the shuttle valve
are maintained when the aliquot sample of fluid is removed from the
first fluid path and transferred to the second fluid path.
In a further exemplary embodiment, the apparatus for analyzing a
sample comprises (i) a chromatography column; (ii) two or more
non-destructive detectors with no destructive detectors within the
system; (iii) a fraction collector in fluid communication with the
two or more non-destructive detectors, the fraction collector being
operatively adapted to collect one or more sample fractions in
response to one or more detector signals from the two or more
non-destructive detectors.
In an even further embodiment according to the present invention,
an apparatus for analyzing a sample using flash chromatography
includes an evaporative particle detector that is capable of
detecting individual compounds in the sample; and a fraction
collector that is capable of responding to a change in a detector
response of the detected compound, wherein the evaporative particle
detector is the only detector utilized to analyze the sample. The
evaporative particle detector is capable of detecting chemical
composition, chemical structure, molecular weight, or other
physical or chemical properties. The detector may include an ELSD,
CNLSD or mass spectrometer.
In yet another exemplary embodiment, the apparatus for analyzing a
sample comprises a fraction collector in a liquid chromatography
system, the fraction collector being operatively adapted to (i)
recognize, receive and process one or more signals from at least
one detector, and (ii) collect one or more sample fractions based
on the one or more signals.
The methods and apparatus of the present invention may comprise at
least one detector. Suitable detectors include, but are not limited
to, non-destructive detectors (i.e., detectors that do not consume
or destroy the sample during detection) such as UV, RI,
conductivity, fluorescence, light scattering, viscometry,
polorimetry, and the like; and/or destructive detectors (i.e.,
detectors that consume or destroy the sample during detection) such
as evaporative particle detectors (EPD), e.g., evaporative light
scattering detectors (ELSD), condensation nucleation light
scattering detectors (CNLSD), etc., corona discharge, mass
spectrometry, atomic adsorption, and the like. For example, the
apparatus of the present invention may include at least one UV
detector, at least one evaporative light scattering detector
(ELSD), at least one mass spectrometer (MS), at least one
condensation nucleation light scattering detector (CNLSD), at least
one corona discharge detector, at least one refractive index
detector (RID), at least one fluorescence detector (FD), chiral
detector (CD) or any combination thereof. In one exemplary
embodiment, the detector may comprise one or more evaporative
particle detector(s) (EPD), which allows the use of chromaphoric
and non-chromaphoric solvents as the mobile phase. In a further
embodiment, a non-destructive detector may be combined with a
destructive detector, which enables detection of various compound
specific properties, molecular weight, chemical structure,
elemental composition and chirality of the sample, such as, for
example, the chemical entity associated with the peak.
The present invention is even further directed to computer readable
medium having stored thereon computer-executable instructions for
performing one or more of the method steps in any of the exemplary
methods described herein. The computer readable medium may be used
to load application code onto an apparatus or an apparatus
component, such as any of the apparatus components described
herein, in order to (i) provide interface with an operator and/or
(ii) provide logic for performing one or more of the method steps
described herein.
These and other features and advantages of the present invention
will become apparent after a review of the following detailed
description of the disclosed embodiments and the appended
claims.
BRIEF DESCRIPTION OF THE FIGURES
FIG. 1 depicts an exemplary liquid chromatography system of the
present invention comprising a splitter pump to actively control
fluid flow to a detector;
FIG. 2 depicts another exemplary liquid chromatography system of
the present invention comprising a splitter pump and a
detector;
FIG. 3A depicts an exemplary liquid chromatography system of the
present invention comprising a shuttle valve and a detector;
FIGS. 3B-3C depict the operation of an exemplary shuttle valve
suitable for use in the present invention;
FIG. 4 depicts an exemplary liquid chromatography system of the
present invention comprising a splitter pump and two detectors;
FIG. 5 depicts an exemplary liquid chromatography system of the
present invention comprising two splitter pumps and two
detectors;
FIG. 6 depicts an exemplary liquid chromatography system of the
present invention comprising a shuttle valve and two detectors;
FIG. 7 depicts an exemplary liquid chromatography system of the
present invention comprising two shuttle valves and two
detectors;
FIG. 8 depicts an exemplary liquid chromatography system of the
present invention comprising a splitter pump, an evaporative light
scattering detector (ELSD), and an ultraviolet (UV) detector;
FIG. 9 depicts another exemplary liquid chromatography system of
the present invention comprising a splitter pump, an ELSD and an UV
detector;
FIGS. 10A-10C depict the operation of an exemplary shuttle valve
suitable for use in the present invention; and
FIG. 11 depicts a chromatogram produced from the separation of a
two component mixture using an exemplary chromatography system of
the present invention.
DETAILED DESCRIPTION OF THE INVENTION
To promote an understanding of the principles of the present
invention, descriptions of specific embodiments of the invention
follow and specific language is used to describe the specific
embodiments. It will nevertheless be understood that no limitation
of the scope of the invention is intended by the use of specific
language. Alterations, further modifications, and such further
applications of the principles of the present invention discussed
are contemplated as would normally occur to one ordinarily skilled
in the art to which the invention pertains.
It must be noted that as used herein and in the appended claims,
the singular forms "a", "and", and "the" include plural referents
unless the context clearly dictates otherwise. Thus, for example,
reference to "a solvent" includes a plurality of such solvents and
reference to "solvent" includes reference to one or more solvents
and equivalents thereof known to those skilled in the art, and so
forth.
"About" modifying, for example, the quantity of an ingredient in a
composition, concentrations, volumes, process temperatures, process
times, recoveries or yields, flow rates, and like values, and
ranges thereof, employed in describing the embodiments of the
disclosure, refers to variation in the numerical quantity that may
occur, for example, through typical measuring and handling
procedures; through inadvertent error in these procedures; through
differences in the ingredients used to carry out the methods; and
like proximate considerations. The term "about" also encompasses
amounts that differ due to aging of a formulation with a particular
initial concentration or mixture, and amounts that differ due to
mixing or processing a formulation with a particular initial
concentration or mixture. Whether modified by the term "about" the
claims appended hereto include equivalents to these quantities.
As used herein, the term "chromatography" means a physical method
of separation in which the components to be separated are
distributed between two phases, one of which is stationary
(stationary phase) while the other (the mobile phase) moves in a
definite direction.
As used herein, the term "liquid chromatography" means the
separation of mixtures by passing a fluid mixture dissolved in a
"mobile phase" through a column comprising a stationary phase,
which separates the analyte (i.e., the target substance) from other
molecules in the mixture and allows it to be isolated.
As used herein, the term "mobile phase" means a fluid liquid, a
gas, or a supercritical fluid that comprises the sample being
separated and/or analyzed and the solvent that moves the sample
comprising the analyte through the column. The mobile phase moves
through the chromatography column or cartridge (i.e., the container
housing the stationary phase) where the analyte in the sample
interacts with the stationary phase and is separated from the
sample.
As used herein, the term "stationary phase" means material fixed in
the column or cartridge that selectively adsorbs the analyte from
the sample in the mobile phase separation of mixtures by passing a
fluid mixture dissolved in a "mobile phase" through a column
comprising a stationary phase, which separates the analyte to be
measured from other molecules in the mixture and allows it to be
isolated.
As used herein, the term "flash chromatography" means the
separation of mixtures by passing a fluid mixture dissolved in a
"mobile phase" under pressure through a column comprising a
stationary phase, which separates the analyte (i.e., the target
substance) from other molecules in the mixture and allows it to be
isolated.
As used herein, the term "shuttle valve" means a control valve that
regulates the supply of fluid from one or more source(s) to another
location. The shuttle valve may utilize rotary or linear motion to
move a sample from on fluid to another.
As used herein, the term "fluid" means a gas, liquid, and
supercritical fluid.
As used herein, the term "laminar flow" means smooth, orderly
movement of a fluid, in which there is no turbulence, and any given
subcurrent moves more or less in parallel with any other nearby
subcurrent.
As used herein, the term "substantially" means within a reasonable
amount, but includes amounts which vary from about 0% to about 50%
of the absolute value, from about 0% to about 40%, from about 0% to
about 30%, from about 0% to about 20% or from about 0% to about
10%.
The present invention is directed to methods of analyzing samples
and collecting sample fractions. The present invention is further
directed to apparatus capable of analyzing samples and collecting
sample fractions. The present invention is even further directed to
computer software suitable for use in an apparatus or apparatus
component that is capable of analyzing samples and collecting
sample fractions, wherein the computer software enables the
apparatus to perform one or more method steps as described
herein.
A description of exemplary methods of analyzing samples and
apparatus capable of analyzing samples is provided below.
I. Methods of Analyzing Samples
The present invention is directed to methods of analyzing samples
and collecting sample fractions. The methods of analyzing a sample
may contain a number of process steps, some of which are described
below.
A. Active Control of Fluid Flow to a Detector
In some embodiments of the present invention, the method of
analyzing a sample comprises a step comprising actively controlling
fluid flow to a detector via a splitter pump or a shuttle valve.
One exemplary liquid chromatography system depicting such a method
step is shown in FIG. 1. As shown in FIG. 1, exemplary liquid
chromatography system 10 comprises (i) a chromatography column 11,
(ii) a tee 12 having a first inlet 21, a first outlet 22 and a
second outlet 23, (iii) a fraction collector 14 in fluid
communication with first outlet 22 of tee 12, (iv) a first detector
13 in fluid communication with second outlet 23 of tee 12, and (v)
a splitter pump 15 positioned in fluid communication with second
outlet 23 of tee 12 and first detector 13.
In this exemplary system, splitter pump 15 actively controls fluid
flow to first detector 13. As used herein, the phrase "actively
controls" refers to the ability of a given splitter pump or shuttle
valve to control fluid flow through a given detector even though
there may be changes in fluid flow rate in other portions of the
liquid chromatography system. Unlike "passive" flow splitters that
merely split fluid flow, the splitter pumps and shuttle valves used
in the present invention control fluid flow to at least one
detector regardless of possible fluctuations in fluid flow within
the liquid chromatography system such as, for example, flow
restrictions, total flow rate, temperature, and/or solvent
composition.
The step of actively controlling fluid flow to a given detector may
comprise, for example, sending an activation signal to the splitter
pump or shuttle valve to (i) activate the splitter pump or shuttle
valve, (ii) deactivate the splitter pump or shuttle valve, (iii)
change one or more flow and/or pressure settings of the splitter
pump or shuttle valve, or (iv) any combination of (i) to (iii).
Suitable flow and pressure settings include, but are not limited
to, (i) a valve position, (ii) splitter pump or shuttle valve
pressure, (iii) air pressure to a valve, or (iv) any combinations
of (i) to (iii). Typically, the activation signal is in the form
of, for example, an electrical signal, a pneumatic signal, a
digital signal, or a wireless signal.
As shown in FIG. 1, in exemplary liquid chromatography system 10,
the step of actively controlling fluid flow to detector 13
comprises using splitter pump 15 to pump fluid from tee 12 into
detector 13. In other embodiments, the step of actively controlling
fluid flow to a detector may comprise using a splitter pump to pull
fluid through a detector. Such a system configuration is shown in
FIG. 2.
FIG. 2 depicts exemplary liquid chromatography system 20 comprises
chromatography column 11; tee 12 having first inlet 21, first
outlet 22 and second outlet 23; fraction collector 14 in fluid
communication with first outlet 22 of tee 12; first detector 13 in
fluid communication with second outlet 23 of tee 12; and splitter
pump 15 positioned so as to pull fluid through detector 13 from
second outlet 23 of tee 12.
In some desired embodiments, a shuttle valve, such as exemplary
shuttle valve 151 shown in FIGS. 3A-3C is used to actively control
fluid flow to a detector such as detector 131. As shown in FIG. 3A,
exemplary liquid chromatography system 30 comprises chromatography
column 11; shuttle valve 151 having chromatography cartridge inlet
111, fraction collector outlet 114, gas or liquid inlet 115 and
detector outlet 113; fraction collector 14 in fluid communication
with fraction collector outlet 114 of shuttle valve 151; first
detector 131 in fluid communication with detector outlet 113 of
shuttle valve 151; and fluid supply 152 providing fluid to gas or
liquid inlet 115 of shuttle valve 151.
In an even further exemplary embodiment of the present invention, a
method of analyzing a sample of fluid using chromatography includes
the steps of providing a first fluid of effluent from a
chromatography column; providing a second fluid to carry the sample
of fluid to at least one detector; using a shuttle valve to remove
an aliquot sample of fluid from the first fluid and transfer the
aliquot to the second fluid while maintaining a continuous path of
the second fluid through the shuttle valve; using at least one
detector to observe the aliquot sample of fluid; and collecting a
new sample fraction of the first fluid in a fraction collector in
response to a change in a detector response. In one embodiment, a
continuous flow path of the first fluid through the shuttle valve
is maintained when the aliquot sample of fluid is removed from the
first fluid. In another embodiment, continuous flow paths of both
the first fluid and the second fluid through the shuttle valve are
maintained when the aliquot sample of fluid is removed from the
first fluid and transferred to the second fluid.
In another exemplary embodiment according to the present invention,
a method of analyzing a sample of fluid using chromatography
includes the steps of providing a first fluid comprising the
sample; using a shuttle valve to remove an aliquot sample of fluid
from the first fluid without substantially affecting flow
properties of the first fluid through the shuttle valve; using at
least one detector to observe the aliquot sample of fluid; and
collecting a new sample fraction of the first stream in a fraction
collector in response to a change in at least one detector
response. The flow of the first fluid through the shuttle valve may
be substantially laminar, due to the first fluid path or channel
being substantially linear or straight through at least a portion
of the valve. In a further exemplary embodiment, the pressure of
the first fluid through the shuttle valve remains substantially
constant and/or it does not substantially increase. In another
embodiment, the flow rate of the first fluid may be substantially
constant through the shuttle valve. In an alternative embodiment, a
second fluid is utilized to carry the aliquot sample of fluid from
the shuttle valve to the detector(s). The flow of the second fluid
through the shuttle valve may be substantially laminar due to the
second fluid path or channel being substantially linear or straight
through at least a portion of the valve. In an exemplary
embodiment, the pressure of the second fluid through the shuttle
valve is substantially constant and/or it does not substantially
increase. In another embodiment, the flow rate of the second fluid
may be substantially constant through the shuttle valve.
FIGS. 3B-3C depict how a shuttle valve in one exemplary embodiment
operates within a given liquid chromatography system. As shown in
FIG. 3B, shuttle valve 151 comprises chromatography cartridge inlet
111, which provides fluid flow from a chromatography column (e.g.,
column 11) to shuttle valve 151; an incoming sample aliquot volume
116; fraction collector outlet 114, which provides fluid flow from
shuttle valve 151 to a fraction collection (e.g., fraction
collection 14); gas or liquid inlet 115, which provides gas (e.g.,
air, nitrogen, etc.) or liquid (e.g., an alcohol) flow through a
portion of shuttle valve 151; outgoing sample aliquot volume 117;
and detector outlet 113, which provides fluid flow from shuttle
valve 151 to a detector (e.g., detector 131, such as a ELSD).
As fluid flows through shuttle valve 151 from chromatography
cartridge to inlet 111 to fraction collector outlet 114, incoming
sample aliquot volume 116 is filled with a specific volume of fluid
referred to herein as sample aliquot 118 (shown as the shaded area
in FIG. 3B). At a desired time, shuttle valve 151 transfers sample
aliquot 118 within incoming sample aliquot volume 116 into outgoing
sample aliquot volume 117 as shown in FIG. 3C. Once sample aliquot
118 is transferred into outgoing sample aliquot volume 117, gas or
liquid flowing from inlet 115 through outgoing sample aliquot
volume 117 transports sample aliquot 118 to detector 131 (e.g., an
ELSD) via detector outlet 113.
Shuttle valve 151 may be programmed to remove a sample aliquot
(e.g., sample aliquot 118) from a sample for transport to at least
one detector at a desired sampling frequency. In one exemplary
embodiment, the sampling frequency is at least 1 sample aliquot
every 10 seconds (or at least 1 sample aliquot every 5 seconds, or
at least 1 sample aliquot every 3 seconds, or at least 1 sample
aliquot every 2 seconds, or 1 sample aliquot every 0.5 seconds, or
at least 1 sample aliquot every 0.1 seconds).
FIGS. 10A-C depict an exemplary shuttle valve of the present
invention and how it operates within a given liquid chromatography
system. As shown in FIG. 10A, shuttle valve 151 comprises
chromatography cartridge inlet 111, which provides fluid flow from
a chromatography column (e.g., column 11) to shuttle valve 151;
channel 117 connecting inlet 111 to outlet 114; an incoming sample
aliquot volume 118 in dimple 116 of dynamic body 119; fraction
collector outlet 114, which provides fluid flow from shuttle valve
151 to a fraction collection (e.g., fraction collection 14); gas or
liquid inlet 115, which provides gas (e.g., air, nitrogen, etc.) or
liquid (e.g., an alcohol) flow through shuttle valve 151; outgoing
sample aliquot volume 118 in dimple 116; channel 120 connecting
inlet 115 to outlet 113; and detector outlet 113, which provides
fluid flow from shuttle valve 151 to a detector (e.g., detector
131, such as a ELSD).
As fluid flows through shuttle valve 151 from chromatography
cartridge to inlet 111 to fraction collector outlet 114 via channel
117, incoming sample aliquot volume 118 in dimple 116 is filled
with a specific volume of fluid referred to herein as sample
aliquot 118 (shown as the shaded area in FIG. 10A). At a desired
time, shuttle valve 151 transfers sample aliquot 118 within dimple
116 taken from channel 117 to channel 120 by rotating the dimple
116 in dynamic body 119 via dimple rotation path 121. Once sample
aliquot 118 is transferred into channel 120, gas or liquid flowing
from inlet 115 through channel 120 transports sample aliquot 118 to
detector 131 (e.g., an ELSD) via detector outlet 113. Another
advantage of the shuttle valve of the present invention relates to
the fluidics design of the channels through the valve. In order to
minimize backpressure in the chromatography system, the flow
through channels 117 and 120 is continuous. This is accomplished by
locating channels 117 and 120 in static body 122 such that no
matter what position the dynamic body 119 is in, the flow through
shuttle valve 151 is continuous (as shown in FIG. 10B). As shown in
FIG. 10A, at least a portion of the sample stream channel 117 and
detector stream channel 120 may be substantially planar or
circumferential, which reduces turbulence and further minimizes
pressure increase through the valve. In addition, at least a
portion of the sample stream channel 117 and detector stream
channel 120 may be substantially parallel to dimple 116 when
contiguous with it, which further limits turbulent flow and any
increase in pressure in the valve. This includes those
configurations that do not increase pressure within the valve of
more than 50 psi, preferably not more than 30 psi, more preferably
not more than 20 psi, and even more preferably not more than 10, 9,
8, 7, 6, 5, 4, 3, 2, or 1 psi. Dimple 116 is located in the dynamic
body 119 and is in fluid communication with the face of the dynamic
body that is contiguous with the static body 122, whereby when the
dynamic body 119 is in a first position, the dimple 116 will be in
fluid communication with the sample stream channel 117, and when
moved to a second position, the dimple 116 will be in fluid
communication with the detector stream channel 120. The dimple 116
may be of any shape but is depicted as a concave semi sphere, and
it may be or any size. In an exemplary embodiment, the dimple may
be extremely small in size (e.g., less than 2000 nL, preferably
less than about 500 nL, more preferably less than about 100 nL, and
even more preferably less than about 1 nL, but may include any size
from 1 nL to 2000 nL, which allows for rapid sampling. In addition,
small dimple 116 size allows for a very short dimple rotation path
121, which significantly reduces wear on the surfaces of the
dynamic body 119 and the static body 122 and results in a shuttle
valve 151 having extended service life before maintenance is
required (e.g., more than 10 million cycles are possible before
service). Even though a rotary motion shuttle valve is depicted in
FIG. 10A-C, linear motion shuttle valves, or their equivalent, may
be employed in the present invention.
Shuttle valve 151 may be programmed to remove a sample aliquot
(e.g. sample aliquot 118) from a sample for transport to at least
one detector at a desired sampling frequency. In one exemplary
embodiment, the sampling frequency is at least 1sample aliquot
every 10 seconds (or at least 1 sample aliquot every 5 seconds, or
at least 1 sample aliquot every 3 seconds, or at least 1 sample
aliquot every 2seconds, or 1sample aliquot every 0.5 seconds, or at
least 1 sample aliquot every 0.1 seconds). This shuttle valve is
further described in copending U.S. provisional patent application
No. 61/200,814, the entire subject matter of which is incorporated
herein by reference.
In another embodiment, universal carrier fluid, including volatile
liquids and various gases, may be utilized in the chromatography
system to carry a sample to a detector. As shown in FIG. 3A, the
carrier fluid from fluid supply 152 enters the shuttle valve 151 at
inlet 115 where it picks up sample aliquot 118 (shown in FIG. 10A)
and then proceeds via outlet 113 to detector 131. The sample
aliquot should not precipitate in the carrier fluid of the valve or
the associated plumbing may become blocked, or the sample will coat
the walls of the flow path and some or all of the sample will not
reach the detector. Sample composition in flash chromatography is
very diverse, covering a large spectrum of chemical compounds
including inorganic molecules, organic molecules, polymers,
peptides, proteins, and oligonucleotides. Solubility in various
solvents differs both within and between classes of compounds.
Detector compatibility also constrains the types of carrier fluids
that may be used. For example, for UV detection, the solvent should
be non-chromaphoric at the detection wavelength. For evaporative
particle detection (EPD) techniques (ELSD, CNLSD, Mass spec, etc.),
the solvent should be easily evaporated at a temperature well below
the sample's melting point. In addition, the carrier fluid should
be miscible with the sample flowing between the valve inlet 111 and
the fraction collector outlet 114. For example, if hexane is used
in one flow path, water may not be used in the other flow path
because the two are not miscible. All the above suggests the
carrier fluid should be customized each time the separation
solvents change. This is time consuming and impractical. According
to an exemplary embodiment of the present invention, using solvents
that are miscible with organic solvents and water, volatile, and
non-chromaphoric, averts this problem. For example, a volatile,
non-chromaphoric medium polarity solvent, such as isopropyl alcohol
(IPA), may be used as the carrier fluid. IPA is miscible with
almost all solvents, is non-chromaphoric at common UV detection
wavelengths, and is easily evaporated at low temperatures. In
addition, IPA dissolves a broad range of chemicals and chemical
classes. IPA is thus a suitable carrier fluid for virtually all
sample types. Other carrier fluids may include acetone, methanol,
ethanol, propanol, butanol, isobutanol, tetrahydrofuran, and the
like. In an alternative exemplary embodiment, a gas may be utilized
as the carrier fluid. Sample precipitation is not encountered
because the sample remains in the separation solvent, or mobile
phase, through the shuttle valve and subsequently through the
detector. Likewise, the separation solvent, or mobile phase, never
mixes with another solvent so miscibility is not an issue. Because
the carrier is a gas, volatility is no longer an issue. In
addition, most gasses are non-chromaphoric and compatible with UV
detection. When using gas as the carrier, the sample aliquot 118 is
issued from the valve 151 to the detector 131 as discrete slugs
sandwiched between gas pockets 123 as shown in FIG. 10C. Using gas
as the carrier fluid has other advantages. For example, when used
with an evaporative light scattering detector or other detection
technique where the sample is nebulized, the gas may be used to
transport the sample and nebulize the sample, eliminating the need
for a separate nebulizer gas supply. In addition, because gas does
not require evaporation, ambient drift tube temperatures may be
used eliminating the need for drift tube heaters. A broader range
of samples may be detected because those that would evaporate at
higher temperatures will now stay in the solid or liquid state as
they pass through the drift tube. A variety of gasses may be used
as the carrier gas including air, nitrogen, helium, hydrogen and
carbon dioxide. Supercritical fluids may also be used, such as
supercritical carbon dioxide.
B. Detection of a Sample Component within a Fluid Stream
The methods of the present invention may further comprise using at
least one detector to detect one or more sample components within a
fluid stream. Suitable detectors for use in the liquid
chromatography systems of the present invention include, but are
not limited to, non-destructive and/or destructive detectors.
Suitable detectors include, but are not limited to, non-destructive
detectors (i.e., detectors that do not consume or destroy the
sample during detection) such as UV, RI, conductivity,
fluorescence, light scattering, viscometry, polorimetry, and the
like; and/or destructive detectors (i.e., detectors that consume or
destroy the sample during detection) such as evaporative particle
detectors (EPD), e.g., evaporative light scattering detectors
(ELSD), condensation nucleation light scattering detectors (CNLSD),
etc., corona discharge, mass spectrometry, atomic adsorption, and
the like. For example, the apparatus of the present invention may
include at least one UV detector, at least one evaporative light
scattering detector (ELSD), at least one mass spectrometer (MS), at
least one condensation nucleation light scattering detector
(CNLSD), at least one corona discharge detector, at least one
refractive index detector (RID), at least one fluorescence detector
(FD), at least one chiral detector (CD), or any combination
thereof. In one exemplary embodiment, the detector may comprise one
or more evaporative particle detector(s) (EPD), which allows the
use of chromaphoric and non-chromaphoric solvents as the mobile
phase. In a further embodiment, a non-destructive detector may be
combined with a destructive detector, which enables detection of
various compound specific properties of the sample, such as, for
example, the chemical entity, chemical structure, molecular weight,
etc., associated with each chromatographic peak. When combined with
mass spectrometer detection, the fraction's chemical structure
and/or molecular weight may be determined at the time of detection,
streamlining identification of the desired fraction. In current
systems the fraction's chemical identity and structure must be
determined by cumbersome past-separation techniques.
Regardless of the type of detector used, a given detector provides
one or more detector responses that may be used to generate and
send a signal to one or more components (e.g., a fraction
collector, another detector, a splitter pump, a shuttle valve, or a
tee) within a liquid chromatography system as described herein.
Typically, a change in a given detector response triggers the
generation and sending of a signal. In the present invention, a
change in a given detector response that might trigger the
generation and sending of a signal to one or more components
includes, but is not limited to, a change in a detector response
value, reaching or exceeding a threshold detector response value, a
slope of the detector response value over time, a threshold slope
of the detector response value over time, a change in a slope of
the detector response value over time, a threshold change in a
slope of the detector response value over time, or any combination
thereof.
In some exemplary embodiments, the liquid chromatography system of
the present invention comprises at least two detectors as shown in
FIG. 4. Exemplary liquid chromatography system 40 shown in FIG. 4
comprises chromatography column 11; tee 12 having first inlet 21,
first outlet 22 and second outlet 23; fraction collector 14 in
fluid communication with first outlet 22 of tee 12; first detector
13 in fluid communication with second outlet 23 of tee 12; splitter
pump 15 actively controlling fluid flow to first detector 13 from
second outlet 23 of tee 12; and second detector 16 in fluid
communication with second outlet 23 of tee 12.
When two or more detectors are present, the liquid chromatography
system provides more analysis options to an operator. For example,
in exemplary liquid chromatography system 40 shown in FIG. 4, a
method of analyzing a sample may comprise a step of sending one or
more signals from first detector 13 (e.g., an ELSD) and/or second
detector 16 (e.g., an optical absorbance detector such as an UV
detector) to fraction collector 14 instructing fraction collector
14 to collect a new sample fraction. The one or more signals from
first detector 13 and/or second detector 16 may comprise a single
signal from first detector 13 or second detector 16, two or more
signals from first detector 13 and second detector 16, or a
composite signal from first detector 13 and second detector 16. In
exemplary liquid chromatography system 40 shown in FIG. 4, the
method of analyzing a sample may further comprise a step of sending
a signal from second detector 16 to splitter pump 15 instructing
splitter pump 15 to initiate or stop fluid flow to first detector
13 in response to second detector 16 detecting a sample component
in a fluid stream.
In other exemplary embodiments, the liquid chromatography system of
the present invention comprises at least two detectors and at least
two splitter pumps as shown in FIG. 5. Exemplary liquid
chromatography system 50 shown in FIG. 5 comprises chromatography
column 11; first tee 12 having first inlet 21, first outlet 22 and
second outlet 23; first detector 13 in fluid communication with
second outlet 23 of first tee 12; first splitter pump 15 actively
controlling fluid flow to first detector 13 from second outlet 23
of first tee 12; second tee 18 having first inlet 31, first outlet
32 and second outlet 33; second detector 16 in fluid communication
with second outlet 33 of second tee 18; second splitter pump 17
actively controlling fluid flow to second detector 16 from second
outlet 33 of second tee 18; and fraction collector 14 in fluid
communication with second outlet 32 of second tee 18.
As discussed above, the liquid chromatography systems of the
present invention may comprise one or more shuttle valves in place
or one or more tee/splitter pump combinations to actively control
fluid flow to at least one detector as exemplified in FIGS. 6-7. As
shown in FIG. 6, exemplary liquid chromatography system 60
comprises chromatography column 11; shuttle valve 151 having
chromatography cartridge inlet 111, fraction collector outlet 114,
gas or liquid inlet 115 and detector outlet 113; fraction collector
14 in fluid communication with fraction collector outlet 114 of
shuttle valve 151; first detector 131 in fluid communication with
detector outlet 113 of shuttle valve 151; fluid supply 152
providing fluid to gas or liquid inlet 115 of shuttle valve 151;
and second detector 161 in fluid communication with detector outlet
113 of shuttle valve 151.
As shown in FIG. 7, exemplary liquid chromatography system 70
comprises chromatography column 11; first shuttle valve 151 having
chromatography cartridge inlet 111, fraction collector outlet 114,
gas or liquid inlet 115 and detector outlet 113; first detector 131
in fluid communication with detector outlet 113 of shuttle valve
151; fluid supply 152 providing fluid to gas or liquid inlet 115 of
shuttle valve 151; second shuttle valve 171 having chromatography
cartridge inlet 121, fraction collector outlet 124, gas or liquid
inlet 125 and detector outlet 123; second detector 161 in fluid
communication with detector outlet 123 of shuttle valve 171; fluid
supply 172 providing fluid to gas or liquid inlet 125 of shuttle
valve 171; and fraction collector 14 in fluid communication with
fraction collector outlet 124 of shuttle valve 171.
In these exemplary embodiments, namely, exemplary liquid
chromatography systems 50 and 70, a method of analyzing a sample
may further comprise a step of actively controlling fluid flow to
second detector 16 (or second detector 161) via second splitter
pump 17 (or second shuttle valve 171), as well as actively
controlling fluid flow to first detector 13 (or first detector 131)
via first splitter pump 15 (or first shuttle valve 151). Although
not shown in FIG. 5, it should be understood that first splitter
pump 15 and/or second splitter pump 17 may be positioned within
exemplary liquid chromatography system 50 so as to push or pull
fluid through first detector 13 and second detector 16
respectively.
In some exemplary embodiments, one or more optical absorbance
detectors, such as one or more UV detectors, may be used to observe
detector responses and changes in detector responses at one or more
wavelengths across the absorbance spectrum. In these embodiments,
one or more light sources may be used in combination with multiple
sensors within a single detector or multiple detectors to detect
light absorbance by a sample at multiple wavelengths. For example,
one or more UV detectors may be used to observe detector responses
and changes in detector responses at one or more wavelengths across
the entire UV absorbance spectrum.
In one exemplary method of analyzing a sample, the method comprises
the step of using an optical absorbance detector, such as an UV
detector, comprising n sensors to observe a sample at n specific
wavelengths across the entire UV absorbance spectrum; and
collecting a new sample fraction in response to (i) a change in any
one of the n detector responses at the n specific UV wavelengths,
or (ii) a change in a composite response represented by the n
detector responses. The n sensors and multiple detectors, when
present, may be positioned relative to one another as desired to
affect signal timing to a fraction collector and/or another system
component (e.g., another UV detector).
When utilizing whole-spectrum UV (or other spectrum range)
analysis, the spectrum may be divided into any desired number of
ranges of interest (e.g., every 5 nm range from 200 nm to 400 nm).
Any significant change over time in each spectrum range may be
monitored. A sudden drop in received light energy (e.g., a drop in
both the first and second derivative of the detector response)
within a given range may indicate the arrival of a substance that
absorbs light in the given wavelength range of interest. In this
exemplary embodiment, the width of each range can be made smaller
to increase precision; alternatively, the width of each range can
be made larger so as to reduce the burden of calculation (i.e.,
fewer calculations per second, less memory required).
In other exemplary embodiments, a plurality of different types of
detectors may be used to observe a variety of detector responses
and changes in the detector responses within a given system. In
exemplary liquid chromatography system 80 shown in FIG. 8, an
evaporative particle detector (EPD), such as an evaporative light
scattering detector (ELSD) (i.e., first detector 13) is used alone
or in combination with an UV detector (i.e., second detector 16).
Exemplary liquid chromatography system 80 further comprises
chromatography column 11; tee 12 having first inlet 21, first
outlet 22 and second outlet 23; fraction collector 14; EPD 13 in
fluid communication with second outlet 23 of tee 12; splitter pump
15 actively controlling fluid flow to EPD 13; and UV detector 16 in
fluid communication with first outlet 22 of tee 12. In this
exemplary embodiment, the use of evaporative particle detection
offers several advantages. Non-chromaphoric mobile phases must be
used with UV detection or the mobile phase's background absorbance
would obliterate the sample signal. This precludes using solvents
such as toluene, pyridine and others that have otherwise valuable
chromatographic properties. With evaporative particle detection,
the mobile phase chromaphoric properties are immaterial. As long as
the mobile phase is more volatile than the sample, it may be used
with evaporative particle detection. This opens the opportunity to
improve separations through the use of highly selective
chromaphoric solvents as the mobile phase. Moreover, UV detectors
will not detect non-chromaphoric sample components. Fractions
collected based on UV detection only may contain one or more
unidentifiable non-chromaphoric components, which compromises
fraction purity. Conversely, non-chromaphoric samples may be
completely missed by UV detection and either sent directly to waste
or collected in fractions assumed to be sample-free (blank
fractions). The net result is lost productivity, contaminated
fractions, or loss of valuable sample components. When an EPD
(e.g., ELSD) is utilized alone or with UV detection in the flash
system, chromaphoric and non-chromaphoric components are detected
and collected, improving fraction purity. Because a flash system
that includes UV detector alone may miss sample components or
incorrectly flag pure fractions, many flash users will screen
collected fractions by thin layer chromatography to confirm purity
and confirm blank fractions are truly blank. This is a
time-consuming post-separation procedure that slows down workflow.
Those fractions discovered to contain more than one component will
frequently require a second chromatography step to properly
segregate the components.
In exemplary liquid chromatography system 80, signals 31 and 61
from detector (e.g., ELSD) 13 and UV detector 16 respectively may
be sent to fraction collector 14 to initiate some activity from
fraction collector 14 such as, for example, collection of a new
sample fraction. In desired embodiments, in response to one or more
detector signals 31 and 61 from (i) detector ELSD 13, (ii) UV
detector 16, or (iii) both ELSD 13 and UV detector 16, fraction
collector 14 collects a new sample fraction.
Similar to exemplary liquid chromatography system 80, in exemplary
liquid chromatography system 60 shown in FIG. 6, signals 311 and
611 from ELSD 131 and UV detector 161 respectively may be sent to
fraction collector 14 to initiate some activity from fraction
collector 14 such as, for example, collection of a new sample
fraction. In desired embodiments, in response to one or more
detector signals 311 and 611 from (i) ELSD 131, (ii) UV detector
161, or (iii) both ELSD 131 and UV detector 161, fraction collector
14 collects a new sample fraction.
As discussed above, UV detector 16 (or UV detector 161) may
comprise n sensors operatively adapted to observe a sample at n
specific wavelengths across a portion of or the entire UV
absorbance spectrum. In exemplary liquid chromatography system 80
shown in FIG. 8, in response to (i) a single signal from either one
of ELSD 13 or UV detector 16, (ii) two or more signals from both
ELSD 13 and UV detector 16, or (iii) a composite signal comprising
two or more detector responses (i.e., up to n detector responses)
at the two or more specific UV wavelengths (i.e., up to n specific
UV wavelengths), fraction collector 14 collects a new sample
fraction. Similarly, in exemplary liquid chromatography system 60
shown in FIG. 6, in response to (i) a single signal from either one
of ELSD 131 or UV detector 161, (ii) two or more signals from both
ELSD 131 and UV detector 161, or (iii) a composite signal
comprising two or more detector responses (i.e., up to n detector
responses) at the two or more specific UV wavelengths (i.e., up to
n specific UV wavelengths), fraction collector 14 collects a new
sample fraction.
Further, in exemplary liquid chromatography system 80, UV detector
16 may be used to produce a detector signal (not shown) that (1)
results (i) from a single detector response from a single sensor or
(ii) from n detector responses of n sensors with n being greater
than 1, and (2) is sent to at least one of splitter pump 15, ELSD
13 and tee 12. In addition, a detector signal (not shown) resulting
from a detector response in ELSD 13 may be sent to UV detector 16
to change one or more settings of UV detector 16. Similarly, in
exemplary liquid chromatography system 60 shown in FIG. 6, UV
detector 161 may be used to produce a detector signal (not shown)
that (1) results (i) from a single detector response from a single
sensor or (ii) from n detector responses of n sensors with n being
greater than 1, and (2) is sent to at least one of shuttle valve
151 and ELSD 13. In addition, a detector signal (not shown)
resulting from a detector response in ELSD 131 may be sent to UV
detector 161 to change one or more settings of UV detector 161.
As shown in exemplary liquid chromatography system 90 shown in FIG.
9, the position of different types of detectors within a given
system may be adjusted as desired to provide one or more system
process features. In exemplary liquid chromatography system 90,
ELSD 13 is positioned downstream from UV detector 16. In such a
configuration, UV detector 16 is positioned to be able to provide a
detector response and generate signal 61 (e.g., a signal that
results (i) from a single detector response from a single sensor or
(ii) from n detector responses of n sensors with n being greater
than 1) for fraction collector 14 prior to the generation of signal
31 from ELSD 13. UV detector 16 is also positioned to be able to
provide a detector response and generate a signal (not shown)
(e.g., a signal that results (i) from a single detector response
from a single sensor or (ii) from n detector responses of n sensors
with n being greater than 1) for at least one of splitter pump 15,
ELSD 13 and tee 12 so as to activate or deactivate splitter pump
15, ELSD 13 and/or tee 12.
Although not shown, it should be understood that a shuttle valve
may be used in place of tee 12 and splitter pump 15 within
exemplary liquid chromatography system 90 shown in FIG. 9 to
provide similar system process features. In such a configuration,
UV detector 16 is positioned to be able to provide a detector
response and generate signal 61 (e.g., a signal that results (i)
from a single detector response from a single sensor or (ii) from n
detector responses of n sensors with n being greater than 1) for
fraction collector 14 prior to the generation of signal 31 from
ELSD 13. UV detector 16 is also positioned to be able to provide a
detector response and generate a signal (not shown) (e.g., a signal
that results (i) from a single detector response from a single
sensor or (ii) from n detector responses of n sensors with n being
greater than 1) for at least one of a shuttle valve and ELSD 13 so
as to activate or deactivate the shuttle valve and/or ELSD 13. Even
though systems 60, 80, and 90 refer to ELSD and UV as the
detectors, any destructive detector, such as EPD, may be utilized
for the ELSD, and any non-destructive detector may be utilized in
place of the UV detector.
In other exemplary embodiments, the liquid chromatography system of
the present invention may comprise a non-destructive system
comprising two or more non-destructive detectors (e.g., one or more
optical absorbance detectors, such as the UV detectors described
above) with no destructive detectors (e.g., a mass spectrometer)
present in the system. In one exemplary embodiment, the liquid
chromatography system comprises two optical absorbance detectors
such as UV detectors, and the method of analyzing a sample
comprises the step of using two or more detectors to observe a
sample at two or more specific wavelengths; and collecting a new
sample fraction in response to (i) a change in a first detector
response at a first wavelength, (ii) a change in a second detector
response at a second wavelength, or (iii) a change in a composite
response represented by the first detector response and the second
detector response. In these embodiments, the first wavelength may
be substantially equal to or different from the second
wavelength.
In embodiments utilizing two or more optical absorbance detectors,
such as two or more UV detectors, the optical absorbance detectors
may be positioned within a given liquid chromatography system so as
to provide one or more system advantages. The two or more optical
absorbance detectors may be positioned in a parallel relationship
with one another so that a sample reaches each detector at
substantially the same time, and the two or more optical absorbance
detectors may produce and send signals (i.e., from first detector
and second detector responses) at substantially the same time to a
fraction collector.
In a further embodiment, a non-destructive detector (e.g., RI
detector, UV detector, etc.) may be used alone or in combined with
a destructive detector (e.g., EPD, mass spectrometer,
spectrophotometer, emission spectroscopy, NMR, etc.). For example,
a destructive detector, such as a mass spectrometer detector,
enables simultaneous detection of the component peak and chemical
entity associated with the peak. This allows for immediate
determination of the fraction that contains the target compound.
With the other detection techniques, post separation determination
of which fraction contains the target compound may be required,
such as by, for example, spectrophotometry, mass spectrometry,
emission spectroscopy, NMR, etc. If two or more chemical entities
elute at the same time from the flash cartridge (i.e., have the
same retention time), they will be deposited in the same vial by
the system when using certain detectors (i.e., those detectors that
cannot identify differences between the chemical entities) because
these detectors cannot determine chemical composition. In an
exemplary embodiment where a mass spectrometer detector is utilized
as the destructive detector, all compounds that elute at the same
time may be identified. This eliminates the need to confirm purity
after separation.
In any of the above-described liquid chromatography systems, it may
be advantageous to position at least one detector, such as at least
one UV detector, downstream from (e.g., in series with) at least
one other detector, such as at least one other UV detector or an
ELSD. In such an embodiment, a first detector response in a first
detector can be used to produce and send a signal to at least one
of (1) a splitter pump, (2) a shuttle valve, (3) a second detector
and (4) a tee. For example, a first detector response in a first
detector can be used to produce and send a signal to a splitter
pump or a shuttle valve to (i) activate the splitter pump or the
shuttle valve, (ii) deactivate the splitter pump or the shuttle
valve, (iii) change one or more flow or pressure settings of the
splitter pump or the shuttle valve, or (iv) any combination of (i)
to (iii). Suitable flow and pressure settings include, but are not
limited to, the flow and pressure settings described above.
Typically, the signal is in the form of, for example, an electrical
signal, a pneumatic signal, a digital signal, or a wireless
signal.
In some embodiments, multiple detectors (i.e., two or more
detectors) may be positioned so that each detector can send a
signal to at least one of (1) a splitter pump, (2) a shuttle valve,
(3) another detector and (4) a tee independently of the other
detectors in the system. For example, multiple optical absorbance
detectors (e.g., UV detectors) may be positioned within a given
system to provide independent signals to a shuttle valve to cause
the shuttle valve to provide actively controlled fluid sampling to
another detector such as an ELSD.
In other embodiments, a first detector response in a first detector
can be used to produce and send a signal to a second detector to
(i) activate the second detector, (ii) activate the second detector
at a wavelength substantially similar to a first wavelength used in
the first detector, (iii) activate the second detector at a
wavelength other than the first wavelength used in the first
detector, (iv) deactivate the second detector, (v) change some
other setting of the second detector (e.g., the observed wavelength
of the second detector), or (vi) any combination of (i) to (v).
In yet other embodiments, a first detector response in a first
detector can be used to produce and send a signal to a tee to (i)
open a valve or (ii) close a valve so as to start or stop fluid
flow through a portion of the liquid chromatography system. As
discussed above, typically, the signal is in the form of, for
example, an electrical signal, a pneumatic signal, a digital
signal, or a wireless signal.
C. Generation of a Signal from a Detector Response
The methods of the present invention may further comprise the step
of generating a signal from one or more detector responses. In some
embodiments, such as exemplary liquid chromatography system 10
shown in FIG. 1, a single detector detects the presence of a sample
component and produces a detector response based on the presence
and concentration of a sample component within a fluid stream. In
other embodiments, such as exemplary liquid chromatography system
50 shown in FIG. 6, two or more detectors may be used to detect the
presence of one or more sample components, and produce two or more
detector responses based on the presence and concentration of one
or more sample components within a fluid stream.
As discussed above, a given detector provides one or more detector
responses that may be used to generate and send a signal to one or
more components (e.g., a fraction collector, another detector, a
splitter pump, a shuttle valve, or a tee) within a liquid
chromatography system as described herein. Typically, a change in a
given detector response triggers the generation and sending of a
signal. Changes in a given detector response that might trigger the
generation and sending of a signal to one or more components
include, but are not limited to, a change in a detector response
value, reaching or exceeding a threshold detector response value, a
slope of the detector response value over time, a threshold slope
of the detector response value over time, a change in a slope of
the detector response value over time, a threshold change in a
slope of the detector response value over time, or any combination
thereof.
In one exemplary embodiment, the methods of the present invention
comprise the step of generating a detector signal from at least one
detector, the detector signal being generated in response to (i)
the slope of a detector response as a function of time (i.e., the
first derivative of a detector response), (ii) a change in the
slope of the detector response as a function of time (i.e., the
second derivative of the detector response), (iii) optionally, a
threshold detector response value, or (iv) any combination of (i)
to (iii) with desired combinations comprising at least (i) or at
least (ii). In this exemplary embodiment, a substance is recognized
from the shape of the detector response, specifically the first
and/or second derivative of the detector response over time (i.e.,
slope and change in slope, respectively). In particular, a computer
program analyzes the time sequence of detector response values and
measures its rate of change (i.e., the first derivative), and the
rate of the rate of change (i.e., the second derivative). When both
the first derivative and the second derivative are increasing, a
substance is beginning to be detected. Similarly, when both the
first derivative and the second derivative are decreasing, the
substance is ceasing to be detected.
Real-world detector values are typically noisy (e.g., jagged), so
it is desirable to utilize low-pass numerical filtering (e.g.,
smoothing) over time. Consequently, the step of generating a
detector signal from at least one detector desirably further
comprises low-pass numerical filtering of (i) slope data over time,
(ii) change in slope data over time, (iii) optionally, a threshold
detector response value, or (iv) any combination of (i) to (iii) to
distinguish actual changes in (i) slope data over time, (ii) change
in slope data over time, (iii) optionally, a threshold detector
response value, or (iv) any combination of (i) to (iii) from
possible noise in the detector response. In desired embodiments, a
finite impulse response (FIR) filter or infinite impulse response
(IIR) filter may be utilized for low-pass numerical filtering of
data over time (e.g., perhaps just an average of several samples).
Typically, the decision algorithm utilizes a small number of
sequential successes in time as confirmation of a real detector
response/signal, and not noise.
In other embodiments, the method of analyzing a sample may comprise
generating a composite signal comprising a detection response
component from each detector, and collecting a new sample fraction
in response to a change in the composite signal. In these
embodiments, the step of generating a composite signal may comprise
mathematically correlating (i) a detector response value, (ii) the
slope of a given detector response as a function of time (i.e., the
first derivative of a given detector response), (iii) a change in
the slope of the given detector response as a function of time
(i.e., the second derivative of the given detector response), or
(iv) any combination of (i) to (iii) from each detector (i.e., each
of the two or more detectors). For example, in some embodiments,
the composite signal may comprise (i) the product of detector
response values for each detector (i.e., each of two or more
detectors) at a given time, (ii) the product of the first
derivatives of the detector responses at a given time, (iii) the
product of the second derivatives of the detector responses at a
given time, or (iv) any combination of (i) to (iii).
In other embodiments in which a composite signal is used, the step
of generating a composite signal may comprise mathematically
correlating (i) a detector response value, (ii) the slope of a
given detector response as a function of time (i.e., the first
derivative of a given detector response), (iii) a change in the
slope of the given detector response as a function of time (i.e.,
the second derivative of the given detector response), or (iv) any
combination of (i) to (iii) from each sensor within a detector
(i.e., n sensors observing a sample at n specific wavelengths)
alone or in combination with any other detector responses present
in the system. For example, in some embodiments, the composite
signal may comprise (i) the product of detector response values for
each sensor within a detector (i.e., n sensors observing a sample
at n specific wavelengths) and any additional detector response
values from other detectors (e.g., from an ELSD used in combination
with an UV detector) at a given time, (ii) the product of the first
derivatives of the detector responses for each sensor within a
detector (i.e., n sensors observing a sample at n specific
wavelengths) and any additional detector responses from other
detectors at a given time, (iii) the product of the second
derivatives of the detector responses for each sensor within a
detector (i.e., n sensors observing a sample at n specific
wavelengths) and any additional detector responses from other
detectors at a given time, or (iv) any combination of (i) to
(iii).
D. Collection of One or More Sample Fractions
The methods of the present invention may further comprise using a
fraction collector, such as exemplary fraction collector 14 shown
in FIGS. 1-3A and 4-9, to collect one or more sample fractions in
response to one or more signals from at least one detector in a
given liquid chromatography system. For example, in exemplary
liquid chromatography systems 10, 20 and 30 shown in FIGS. 1, 2 and
3A respectively, methods of analyzing a sample may further comprise
the step of collecting one or more sample fractions in response to
one or more signals from first detector 13. In exemplary liquid
chromatography systems 40, 50 and 60 shown in FIGS. 4, 5 and 6
respectively, methods of analyzing a sample may further comprise
the step of collecting one or more sample fractions in response to
one or more signals from first detector 13 (or first detector 131),
second detector 16 (or second detector 161), or both first and
second detectors 13 and 16 (or both first and second detectors 131
and 161).
In some embodiments of the present invention, the fraction
collector is operatively adapted to recognize, receive and process
one or more signals from at least one detector, and collect one or
more sample fractions based on the one or more signals. In other
embodiments, additional computer or microprocessing equipment is
utilized to process one or more signals from at least one detector
and subsequently provide to the fraction collector a recognizable
signal that instructs the fraction collector to collect one or more
sample fractions based on one or more signals from the additional
computer or microprocessing equipment.
As discussed above, system components may be positioned within a
given liquid chromatography system to provide one or more system
properties. For example, at least one detector may be positioned
within a given liquid chromatography system so as to minimize any
time delay between (i) the detection of a given detector response
and (ii) the step of collecting a sample fraction based on a signal
generated from the detector response. In exemplary embodiments of
the present invention, the liquid chromatography system desirably
exhibits a maximum time delay of a given detector signal to the
fraction collector (i.e., the time delay between (i) the detection
of a given detector response and (ii) the step of collecting a
sample fraction based on a signal generated from the detector
response) of less than about 2.0 seconds (s) (or less than about
1.5 s, or less than about 1.0 s, or less than about 0.5 s).
In exemplary embodiments of the present invention utilizing two or
more detectors or at least one detector comprising n sensors (as
described above), the liquid chromatography system desirably
exhibits a maximum time delay for any detector signal from any
detector to the fraction collector (i.e., the time delay between
(i) the detection of a given detector response and (ii) the step of
collecting a sample fraction based on a signal (e.g., single or
composite signal) generated from the detector response) of less
than about 2.0 s (or less than about 1.5 s, or less than about 1.0
s, or less than about 0.5 s).
E. Sample Component(s) Separation Step
The methods of the present invention utilize a liquid
chromatography (LC) step to separate compounds within a given
sample. Depending on the particular sample, various LC columns,
mobile phases, and other process step conditions (e.g., feed rate,
gradient, etc.) may be used.
A number of LC columns may be used in the present invention. In
general, any polymer or inorganic based normal phase, reversed
phase, ion exchange, affinity, hydrophobic interaction, hydrophilic
interaction, mixed mode and size exclusion columns may be used in
the present invention. Exemplary commercially available columns
include, but are not limited to, columns available from Grace
Davison Discovery Sciences under the trade names VYDAC.RTM.,
GRACERESOLV.TM., DAVISIL.RTM., ALLTIMA.TM., VISION.TM.,
GRACEPURE.TM., EVEREST.RTM., and DENALI.RTM., as well as other
similar companies.
A number of mobile phase components may be used in the present
invention. Suitable mobile phase components include, but are not
limited to, acetonitrile, dichloromethane, ethyl acetate, heptane,
acetone, ethyl ether, tetrahydrofuran, chloroform, hexane,
methanol, isopropyl alcohol, water, ethanol, buffers, and
combinations thereof.
F. User Interface Steps
The methods of analyzing a sample in the present invention may
further comprise one or more steps in which an operator or user
interfaces with one or more system components of a liquid
chromatography system. For example, the methods of analyzing a
sample may comprise one or more of the following steps: inputting a
sample into the liquid chromatography system for testing; adjusting
one or more settings (e.g., flow or pressure settings, wavelengths,
etc.) of one or more components within the system; programming at
least one detector to generate a signal based on a desired
mathematical algorithm that takes into account one or more detector
responses from one or more sensors and/or detectors; programming
one or more system components (other than a detector) to generate a
signal based on a desired mathematical algorithm that takes into
account one or more detector responses; programming a fraction
collector to recognize a signal (e.g., a single or composite
signal) from at least one detector, and collect one or more sample
fractions based on a received signal; programming one or more
system components (other than a fraction collector) to recognize an
incoming signal from at least one detector, convert the incoming
signal into a signal recognizable and processible by a fraction
collector so that the fraction collector is able to collect one or
more sample fractions based on input from the one or more system
components; and activating or deactivating one or more system
components (e.g., a tee valve, a splitter pump, a shuttle valve or
a detector) at a desired time or in response to some other activity
within the liquid chromatography system (e.g., a detector response
displayed to the operator or user).
II. Apparatus for Analyzing Samples
The present invention is also directed to an apparatus and
apparatus components capable of analyzing a sample or capable of
contributing to the analysis of a sample using one or more of the
above-described method steps.
As described above, in some exemplary embodiments of the present
invention, an apparatus for analyzing a sample may comprise (i) a
chromatography column; (ii) a tee having a first inlet, a first
outlet and a second outlet; (iii) a fraction collector in fluid
communication with the first outlet of the tee; (iv) a first
detector in fluid communication with the second outlet of the tee;
and (v) a splitter pump positioned in fluid communication with the
second outlet of the tee and the first detector with the splitter
pump being operatively adapted to actively control fluid flow to
the first detector. In other exemplary embodiments of the present
invention, a shuttle valve may be used in place of a tee/splitter
pump combination to actively control fluid flow to the first
detector.
Although not shown in FIGS. 1-9, any of the above-described
apparatus (e.g., exemplary liquid chromatography systems 10 to 90)
or apparatus components may further comprise system hardware that
enables (i) the recognition of a detector response value or a
change in a detector response value, (ii) the generation of a
single from the detector response value or a change in a detector
response value, (iii) the sending of a signal to one or more system
components, (iv) the recognition of a generated signal by a
receiving component, (v) processing of the recognized signal within
the receiving component, and (vi) the initiation of a process step
of the receiving component in response to the recognized
signal.
In one embodiments, the apparatus (e.g., exemplary liquid
chromatography systems 10 to 90) or a given apparatus component may
further comprise system hardware that enables a first detector to
send an activation signal to a splitter pump or a shuttle valve to
(i) activate the splitter pump or shuttle valve, (ii) deactivate
the splitter pump or shuttle valve, (iii) change one or more flow
or pressure settings of the splitter pump or shuttle valve, or (iv)
any combination of (i) to (iii). Suitable flow and pressure
settings may include, but are not limited to, (i) a valve position,
(ii) splitter pump or shuttle valve pressure, (iii) air pressure to
a valve, or (iv) any combination of (i) to (iii).
In some embodiments, a splitter pump may be positioned between a
tee and a first detector (see, for example, splitter pump 15
positioned between tee 12 and first detector 13 in FIG. 1). In
other embodiments, a first detector may be positioned between a tee
and the splitter pump (see, for example, first detector 13
positioned between tee 12 and splitter pump 15 in FIG. 2).
In other exemplary embodiments, the apparatus of the present
invention comprise (i) a chromatography column; (ii) two or more
detectors; and (iii) a fraction collector in fluid communication
with the two or more detectors with the fraction collector being
operatively adapted to collect one or more sample fractions in
response to one or more detector signals from the two or more
detectors. In some embodiments, the two or more detectors comprise
two or more non-destructive detectors (e.g., two or more UV
detectors) with no destructive detectors (e.g., mass spectrometer)
in the system.
When two or more detectors are present, a splitter pump or shuttle
valve may be used to split a volume of fluid flow between a first
detector and a second detector. In other embodiments, a splitter
pump or shuttle valve may be used to initiate or stop fluid flow to
one detector in response to a detector response from another
detector. In addition, multiple splitter pumps and/or shuttle
valves may be used in a given system to actively control fluid flow
to two or more detectors.
As discussed above, the apparatus may further comprise system
hardware that enables generation of a detector signal from one or
more detector responses. In one exemplary embodiment, the apparatus
comprises system hardware that enables generation of a detector
signal that is generated in response to (i) the slope of a detector
response as a function of time (i.e., the first derivative of a
detector response), (ii) a change in the slope of the detector
response as a function of time (i.e., the second derivative of the
detector response), (iii) optionally, a threshold detector response
value, or (iv) any combination of (i) to (iii) with desired
combinations comprising at least (i) or at least (ii). The system
hardware desirably further comprises low-pass numerical filtering
capabilities for filtering (i) slope data, (ii) change in slope
data, (iii) optionally, a threshold detector response value, or
(iv) any combination of (i) to (iii) over time to distinguish
actual changes in (i) slope data, (ii) change in slope data, (iii)
optionally, a threshold detector response value, or (iv) any
combination of (i) to (iii) from possible noise in a given detector
response.
In multi-detector systems, system hardware may also be used to
enable the generation of a composite signal comprising a detection
response component from each detector, as well as detection
response components from multiple sensors within a given detector.
In these embodiments, the system hardware is operatively adapted to
send a command/signal to a fraction collector instructing the
fraction collector to collect a new sample fraction in response to
a change in the composite signal. The composite signal may comprise
a mathematical correlation between (i) a detector response value,
(ii) the slope of a given detector response as a function of time
(i.e., the first derivative of a given detector response), (iii) a
change in the slope of the given detector response as a function of
time (i.e., the second derivative of the given detector response),
or (iv) any combination of (i) to (iii) from each detector. For
example, the composite signal may comprise (i) the product of
detector response values for each detector at a given time, (ii)
the product of the first derivatives of the detector responses at a
given time, (iii) the product of the second derivatives of the
detector responses at a given time, or (iv) any combination of (i)
to (iii).
In one desired configuration, the apparatus for analyzing a sample
comprising at least one detector operatively adapted to observe a
sample at two or more specific optical wavelengths (e.g., within
the UV spectrum), and system hardware that enables a fraction
collector to collect a new sample fraction in response to (i) a
change in a detector response at a first wavelength, (ii) a change
in a detector response at a second wavelength, or (iii) a change in
a composite response represented by detector responses at the first
and second wavelengths. Each detector can operate at the same
wavelength(s), at different wavelengths, or multiple wavelengths.
Further, each detector may be in a parallel relationship with one
another, in series with one another, or some combination of
parallel and series detectors.
As discussed above, in one exemplary embodiment, the apparatus may
comprise a single detector comprising n sensors operatively adapted
to observe a sample at n specific optical wavelengths across a
portion of or the entire UV absorbance spectrum (or any other
portion of the absorbance spectrum using some other type of
detector), and system hardware that enables a fraction collector to
collect a new sample fraction in response to (i) a change in any
one of the n detector responses at the n specific optical
wavelengths, or (ii) a change in a composite response represented
by the n detector responses.
When a splitter pump or shuttle valve is present to actively
control fluid flow to at least one detector, the apparatus for
analyzing a sample may further comprise system hardware that
enables generation of an activation signal to the splitter pump or
shuttle valve to (i) activate the splitter pump or shuttle valve,
(ii) deactivate the splitter pump or shuttle valve, (iii) change
one or more flow or pressure settings of the splitter pump or
shuttle valve, or (iv) any combination of (i) to (iii). The
activation signal may be generated, for example, by a system
operator or by a system component, such as a detector (i.e., the
activation signal being generated and sent by the detector in
response to a detector response value or change in a detector
response value of the detector as discussed above).
In an even further embodiment according to the present invention,
an apparatus for analyzing a sample of fluid using chromatography
includes a first fluid path of effluent from a chromatography
column or cartridge; at least one detector that is capable of
analyzing the sample of fluid; and a shuttle valve that transfers
an aliquot sample of fluid from the first fluid path to the
detector(s) without substantially affecting the flow properties of
fluid through the first fluid path. The flow of the fluid through
the first fluid path may be substantially laminar, due to the first
fluid path or channel being substantially linear or straight
through at least a portion of the valve. In a further exemplary
embodiment, the pressure of the fluid through the first fluid path
remains substantially constant and/or it does not substantially
increase. In another embodiment, the flow rate of the fluid may be
substantially constant through the first fluid path. In an
alternative embodiment, a second fluid path is utilized to carry
the aliquot sample of fluid from the shuttle valve to the
detector(s). The flow of fluid through the second fluid path may be
substantially laminar due to the second fluid path or channel being
substantially linear or straight through at least a portion of the
valve. In an exemplary embodiment, the pressure of fluid through
the second fluid path is substantially constant and/or it does not
substantially increase. In further embodiment, the flow rate of
fluid may be substantially constant through the second fluid
path.
In an even further exemplary embodiment, an apparatus for analyzing
a sample of fluid using chromatography includes a first fluid path
of effluent from a chromatography column; a second fluid path that
carries the sample of fluid to at least one detector that is
capable of analyzing the sample; and a shuttle valve that transfers
an aliquot sample of fluid from the first fluid path to the second
fluid path while maintaining a continuous second fluid path through
the shuttle valve. In one embodiment, a continuous first flow path
through the shuttle valve is maintained when the aliquot sample of
fluid is removed from the first fluid path. In another embodiment,
continuous first and second flow paths through the shuttle valve
are maintained when the aliquot sample of fluid is removed from the
first fluid path and transferred to the second fluid path.
In exemplary embodiments of the present invention, the apparatus
for analyzing a sample further comprises a fraction collector that
is operatively adapted to collect one or more sample fractions in
response to one or more detector signals from (i) a first detector,
(ii) a second detector (or any number of additional detectors), or
(iii) both the first and second detectors (or any number of
additional detectors). When multiple detectors are utilized, the
apparatus may comprise a fraction collector operatively adapted to
collect a new sample fraction in response to a change in a
composite signal that accounts for one or more detector responses
from each detector as described above.
As discussed above, in some exemplary embodiments, the apparatus
for analyzing a sample comprises a fraction collector that is
operatively adapted to recognize, receive and process one or more
signals from at least one detector, and collect one or more sample
fractions based on the one or more signals. In other embodiments,
the apparatus for analyzing a sample comprises additional computer
or microprocessing equipment that is capable of processing one or
more signals from at least one detector and converting an incoming
signal into a signal that is recognizable by the fraction
collector. In this later embodiment, the fraction collector
collects one or more sample fractions based on the one or more
signals from the additional computer or microprocessing equipment,
not from signal processing components of the fraction
collector.
It should be noted that any of the above-described exemplary liquid
chromatography systems may comprise any number of detectors,
splitter pumps, tees, and shuttle valves, which may be
strategically placed within a given system to provide one or more
system properties. For example, although not shown in exemplary
liquid chromatography system 60 in FIG. 6, an additional detector
could be positioned between column 11 and shuttle valve 151 and/or
between shuttle valve 151 and detector 161. Although not shown in
exemplary liquid chromatography system 70 in FIG. 7, an additional
detector could be positioned between column 11 and shuttle valve
151 and/or between shuttle valve 151 and shuttle valve 171 and/or
between shuttle valve 171 and fraction collector 14. Additional
detectors may be similarly positioned within exemplary liquid
chromatography systems 80 and 90 shown in FIGS. 8 and 9
respectively,
A number of commercially available components may be used in the
apparatus of the present invention as discussed below.
A. Chromatography Columns
Any known chromatography column may be used in the apparatus of the
present invention. Suitable commercially available chromatography
columns include, but are not limited to, chromatography columns
available from Grace Davison Discovery Sciences (Deerfield, Ill.)
under the trade designations GRACEPURE.TM., GRACERESOLV.TM.,
VYDAC.RTM. and DAVISIL.RTM..
B. Detectors
Any known detector may be used in the apparatus of the present
invention. Suitable commercially available detectors include, but
are not limited to, UV detectors available from Ocean Optics
(Dunedin, Fla.) under the trade designation USB 2000.TM.;
evaporative light scattering detectors (ELSDs) available from Grace
Davison Discovery Sciences (Deerfield, Ill.) under the trade
designation 3300 ELSD.TM.; mass spectrometers (MSs) available from
Waters Corporation (Milford, Mass.) under the trade designation
ZQ.TM.; condensation nucleation light scattering detectors (CNLSDs)
available from Quant (Blaine, Minn.) under the trade designation
QT-500.TM.; corona discharge detectors (CDDs) available from ESA
(Chelmsford, Mass.) under the trade designation CORONA CAD.TM.;
refractive index detectors (RIDs) available from Waters Corporation
(Milford Mass.) under the trade designation 2414; and fluorescence
detectors (FDs) available from Laballiance (St. Collect, Pa.) under
the trade designation ULTRAFLOR.TM..
In some embodiments, a commercially available detector may need to
be modified or programmed or a specific detector may need to be
built in order to perform one or more of the above-described method
steps of the present invention.
C. Splitter Pumps
Any known splitter pump may be used in the apparatus of the present
invention. Suitable commercially available splitter pumps include,
but are not limited to, splitter pumps available from KNF (Trenton,
N.J.) under the trade designation LIQUID MICRO.TM..
D. Shuttle Valves
Any known shuttle valve may be used in the apparatus of the present
invention. Suitable commercially available shuttle valves include,
but are not limited to, shuttle valves available from Valco
(Houston, Tex.) under the trade designation CHEMINERT.TM.,
Rheodyne.RTM. shuttle valve available from Idex Corporation under
the trade name MRA.RTM. and a continuous flow shuttle valve as
described herein.
E. Fraction Collectors
Any known fraction collector may be used in the apparatus of the
present invention. Suitable commercially available fraction
collectors include, but are not limited to, fraction collectors
available from Gilson (Middleton, Wis.) under the trade designation
215.
In some embodiments, a commercially available fraction collector
may need to be modified and/or programmed or a specific fraction
collector may need to be built in order to perform one or more of
the above-described method steps of the present invention. For
example, fraction collectors that are operatively adapted to
recognize, receive and process one or more signals from at least
one detector, and collect one or more sample fractions based on the
one or more signals are not commercially available at this
time.
III. Computer Software
The present invention is further directed to a computer readable
medium having stored thereon computer-executable instructions for
performing one or more of the above-described method steps. For
example, the computer readable medium may have stored thereon
computer-executable instructions for: adjusting one or more
settings (e.g., flow settings, wavelengths, etc.) of one or more
components within the system; generating a signal based on a
desired mathematical algorithm that takes into account one or more
detector responses; recognizing a signal from at least one
detector; collecting one or more sample fractions based on a
received signal; recognizing an incoming signal from at least one
detector, convert the incoming signal into a signal recognizable
and processible by a fraction collector so that the fraction
collector is able to collect one or more sample fractions based on
input from the one or more system components; and activating or
deactivating one or more system components (e.g., a tee valve, a
splitter pump, a shuttle valve, or a detector) at a desired time or
in response to some other activity within the liquid chromatography
system (e.g., a detector response).
IV. Applications/Uses
The above-described methods, apparatus and computer software may be
used to detect the presence of one or more compounds in a variety
of samples. The above-described methods, apparatus and computer
software find applicability in any industry that utilizes liquid
chromatography including, but not limited to, the petroleum
industry, the pharmaceutical industry, analytical labs, etc.
EXAMPLES
The present invention is further illustrated by the following
examples, which are not to be construed in any way as imposing
limitations upon the scope thereof. On the contrary, it is to be
clearly understood that resort may be had to various other
embodiments, modifications, and equivalents thereof which, after
reading the description herein, may suggest themselves to those
skilled in the art without departing from the spirit of the present
invention and/or the scope of the appended claims.
Example 1
In this example, the flash REVELERIS.TM. system (available from
Grace Davison Discovery Sciences) was utilized. 4 mL of a mixture
containing sucrose and aspirin was injected into a 4 g
GRACERESOLV.TM. C18 flash column (available from Grace Davison
Discovery Sciences), which was mounted in the flash system. A 50/50
methanol/water mobile phase was pumped through the system using an
ALLTECH.RTM. model 300 LC pump. The column effluent was directed to
a KNF splitter pump that diverted 300 uL/min of the column effluent
to an ALLTECH.RTM. 3300 ELSD. The balance of the effluent flowed
through an Ocean Optics UV detector to a Gilson fraction
collector.
The sucrose and aspirin were separated on the flash column. Both
the sucrose and the aspirin were detected by the ELSD. The UV
detector only detected the aspirin. Both detectors responded to the
aspirin at the same time. The fraction collector deposited the
sucrose and aspirin in separate collection vials in response to a
composite signal from the UV and ELSD detectors.
Example 2
In this example, the flash REVELERIS.TM. system (available from
Grace Davison Discovery Sciences) was utilized. 4 mL of a mixture
containing dioctyl phthalate and butyl paraben was injected into a
4 g GRACERESOLV.TM. C18 flash cartridge (available from Grace
Davison Discovery Sciences), which was mounted in the flash system.
A 80/20 methanol/water mobile phase was pumped through the system
using an ALLTECH.RTM. model 300 LC pump. The column effluent was
directed to a shuttle valve as described herein that diverted 300
uL/min of the column effluent to an ALLTECH.RTM. 3300 ELSD. The
balance of the effluent flowed through an Ocean Optics UV detector
to a Gilson fraction collector.
This two component mixture contains a non-chromaphoric compound
(one that does not absorb UV light) and a chromaphoric compound.
The non-chromaphoric compound elutes from the flash cartridge
first. FIG. 11 depicts a chromatogram that illustrates only the
ELSD identifies all the components in the sample, as is evidenced
by the two peaks on the chromatogram. The UV detector does not
identify the non-chromaphoric compound (identified as the first
peak by the ELSD), even at two wavelengths. Only the ELSD signal
will be able to properly control the fraction collector, capturing
both compounds. If the UV detector drove the fraction collector,
(as would be the case in conventional Flash systems), the first
compound would be sent to waste or improperly deposited in
collection vessels without knowledge that these fractions contained
desired sample. In conventional flash instruments, all fractions
are screened by thin layer chromatography (TLC) after the
chromatographic separation to find compounds that the UV detector
may not have identified. This Example demonstrates that flash
instruments equipped with an ELSD according to the present
invention are able to identify and separate both chromaphoric and
non-chromaphoric compounds, and post-separation TLC screening is
not required.
While the invention has been described with a limited number of
embodiments, these specific embodiments are not intended to limit
the scope of the invention as otherwise described and claimed
herein. It may be evident to those of ordinary skill in the art
upon review of the exemplary embodiments herein that further
modifications, equivalents, and variations are possible. All parts
and percentages in the examples, as well as in the remainder of the
specification, are by weight unless otherwise specified. Further,
any range of numbers recited in the specification or claims, such
as that representing a particular set of properties, units of
measure, conditions, physical states or percentages, is intended to
literally incorporate expressly herein by reference or otherwise,
any number falling within such range, including any subset of
numbers within any range so recited. For example, whenever a
numerical range with a lower limit, R.sub.L, and an upper limit
R.sub.U, is disclosed, any number R falling within the range is
specifically disclosed. In particular, the following numbers R
within the range are specifically disclosed:
R=R.sub.L+k(R.sub.U-R.sub.L), where k is a variable ranging from 1%
to 100% with a 1% increment, e.g., k is 1%, 2%, 3%, 4%, 5% . . .
50%, 51%, 52% . . . 95%, 96%, 97%, 98%, 99%, or 100%. Moreover, any
numerical range represented by any two values of R, as calculated
above is also specifically disclosed. Any modifications of the
invention, in addition to those shown and described herein, will
become apparent to those skilled in the art from the foregoing
description and accompanying drawings. Such modifications are
intended to fall within the scope of the appended claims. All
publications cited herein are incorporated by reference in their
entirety.
* * * * *